United States Patent |
10,994,999 |
Wilshe
|
May 4, 2021
|
Agricultural composition for facilitating treatment of a plant
Abstract
Disclosed herein is an agricultural composition for facilitating
treatment of a plant, in accordance with some embodiments. Accordingly,
the agricultural composition may include carbanions and a diluting agent.
Further, a carbanion of the carbanions may include a carbon atom.
Further, the carbon atom may include a formal charge of -1. Further, the
diluting agent may be capable of dissolving the carbanions for forming a
solution. Further, the dissolving of the carbanions may include diluting
the carbanions. Further, a ratio of the diluting agent to the carbanions
by volume ranges from 50:1 to 550:1. Further, the dissolving facilitates
at least one application of the solution to the plant.
Inventors: |
Wilshe; Donald Richard (Parrish, FL) |
Applicant: | Name | City | State | Country | Type | Wilshe; Donald Richard | Parrish | FL | US |
|
|
Family ID:
|
75689610
|
Appl. No.:
|
17/115,307 |
Filed:
|
December 8, 2020 |
Related U.S. Patent Documents
| | | | | |
| Application Number | Filing Date | Patent Number | Issue Date | |
---|
| 63046018 | Jun 30, 2020 | | | |
| 63065193 | Aug 13, 2020 | | | |
| 63076598 | Sep 10, 2020 | | | |
|
Current U.S. Class: | 1/1 |
Current CPC Class: |
C05G 3/80 (20200201); C05G 5/27 (20200201); C05G 3/60 (20200201); C05D 9/00 (20130101); C01B 32/05 (20170801); B82Y 40/00 (20130101) |
Current International Class: |
C01B 32/05 (20170101); C05G 3/80 (20200101); C05G 3/60 (20200101); C05G 5/27 (20200101); C05D 9/00 (20060101); B82Y 40/00 (20110101) |
References Cited [Referenced By]
U.S. Patent Documents
Other References Wilshe, Physical Chemistry is the next generation of Agriculture Technology, Parrish, Fl, dated Jan. 5, 2021. cited by applicant. |
Primary Examiner: Langel; Wayne A
Claims
What is claimed is:
1. An agricultural composition for facilitating treatment of a plant, wherein the agricultural composition comprising: carbanions, wherein a carbanion of the carbanions
comprises a carbon atom, wherein the carbon atom comprises a formal charge of -1; and a diluting agent, wherein the diluting agent is capable of dissolving the carbanions for forming a solution, wherein the dissolving of the carbanions comprises
diluting the carbanions, wherein a ratio of the diluting agent to the carbanions by volume ranges from 50:1 to 550:1, wherein the dissolving facilitates at least one application of the solution to the plant.
2. The agricultural composition of claim 1, wherein the ratio of the diluting agent to the carbanions by the volume is 375:1.
3. The agricultural composition of claim 1, wherein the ratio of the diluting agent to the carbanions by the volume is 533:1.
4. The agricultural composition of claim 1, wherein the ratio of the diluting agent to the carbanions by the volume is 320:1.
5. The agricultural composition of claim 1, wherein the ratio of the diluting agent to the carbanions by the volume is 400:1.
6. The agricultural composition of claim 1, wherein the carbanions are derived from at least one organic material, wherein the at least one organic material is associated with at least one plant.
7. The agricultural composition of claim 1, wherein the carbon atom is associated with a hybridization state, wherein the hybridization state is sp3 hybridization state, wherein the carbon atom in the sp3 hybridization state is trivalent,
wherein the carbon atom in the sp3 hybridization state comprises a lone pair of electrons on the carbon atom.
8. The agricultural composition of claim 1, wherein the solution comprises a dispersing agent capable of dispersing the carbanions in the diluting agent, wherein the carbanions are present in the solution in a form of granules, wherein a size
of a granule of the granules is 340 pm (picometer).
9. The agricultural composition of claim 1 further comprising a chelating agent capable of chelating at least one nutrient associated with the plant, wherein the solution is capable of mobilizing the at least one nutrient from the chelating
agent to the plant based on the at least one application of the solution to the plant.
10. The agricultural composition of claim 1, wherein the solution comprises a surface tension reducing agent capable of reducing a surface tension of water associated with the plant, wherein the solution is capable of enhancing an internal
translocation of at least one nutrient associated with the plant through at least one of a xylem system and a phloem system of the plant based on the reducing.
11. The agricultural composition of claim 1, wherein the solution comprises a solvent agent capable of softening a surface of at least one part of the plant based on the at least one application of the solution to the plant, wherein at least
one nutrient enters into at least one circulation pathway of the plant through the surface of the at least one part of the plant based on the softening.
12. The agricultural composition of claim 1, wherein each carbanion of the carbanions is capable of creating an electromechanical reaction with an organic material of at least one organism present on the plant based on the at least one
application of the solution, wherein the creating of the electromechanical reaction disassembles the organic material for eliminating the at least one organism.
13. The agricultural composition of claim 1, wherein the at least one application of the solution comprises dispensing the solution in soil associated with the plant, wherein the carbanions are cable of increasing an electrical conductivity of
the soil based on the dispensing, wherein at least one nutrient transfers from the soil to the plant based on the increasing of the electrical conductivity.
14. A method for producing an agricultural composition to facilitate treatment of a plant, the method comprising: extracting at least one organic material from at least one organic material source, wherein the at least one organic material
comprises a carbon compound; blending the at least one organic material with at least one reagent for forming an agricultural composition preform; applying at least one of a specific temperature and a specific pressure to the agricultural composition
preform, wherein the applying initiates a chemical reaction in the agricultural composition preform, wherein the chemical reaction comprises at least one of a redox reaction and a reduction reaction, wherein the carbon compound is reduced to form
carbanions based on the at least one of the redox reaction and the reduction reaction, wherein a carbon atom of a carbanion of the carbanions comprises a formal charge of -1; and dissolving the carbanions using a diluting agent for forming a solution,
wherein the dissolving of the carbanions comprises diluting the carbanions, wherein a ratio of the diluting agent to the carbanions by volume ranges from 50:1 to 550:1, wherein the dissolving facilitates at least one application of the solution to the
plant.
15. The method of claim 14, wherein the at least one of the redox reaction and the reduction reaction adds a pair of electrons to a carbon atom of the carbon compound for producing the carbanion, wherein the carbon atom is associated with sp3
hybridization state, wherein the carbon atom in the sp3 hybridization state is trivalent, wherein the carbon atom in the sp3 hybridization state comprises a lone pair of electrons on the carbon atom.
16. The method of claim 14, wherein the solution comprises a dispersing agent, wherein the dispersing agent is capable of dispersing the carbanions in the diluting agent, wherein the carbanions are present in the solution in a form of granules,
wherein a size of a granule of the granules is 340 pm (picometer).
17. The method of claim 14 further comprising adding a chelating agent to the solution, wherein the chelating agent is capable of chelating at least one nutrient associated with the plant, wherein the solution is capable of mobilizing the at
least one nutrient from the chelating agent to the plant based on the at least one application of the solution to the plant.
18. The method of claim 14, wherein the solution comprises a surface tension reducing agent, wherein the surface tension reducing agent is capable of reducing a surface tension of water associated with the plant, wherein the solution is capable
of enhancing an internal translocation of at least one nutrient associated with the plant through at least one of a xylem system and a phloem system of the plant based on the reducing.
19. The method of claim 14, wherein the solution comprises a solvent agent, wherein the solvent agent is capable of softening a surface of at least one part of the plant based on the at least one application of the solution to the plant,
wherein at least one nutrient enters into at least one circulation pathway of the plant through the surface of the at least one part of the plant based on the softening.
20. The method of claim 14, wherein each carbanion of the carbanions is capable of creating an electromechanical reaction with an organic material of at least one organism present on the plant based on the at least one application of the
solution, wherein the creating of the electromechanical reaction disassembles the organic material for eliminating the at least one organism.
Description
FIELD OF THE INVENTION
Generally, the present disclosure relates to the field of Drug, bio-affecting, and body treating compositions. More specifically, the present disclosure relates to an agricultural composition for facilitating treatment of a plant.
BACKGROUND OF THE INVENTION
Existing compositions for facilitating treatment of a plant are deficient with regard to several aspects. For instance, existing compositions do not remediate soil. Furthermore, current compositions do not increase the electrical conductivity
of the soil. Moreover, current compositions do not perform fertilizer recovery. Further, the existing compositions do not kill fungi, bacterial, viruses, and insects present on the plant without harming the plant. Further, the existing compositions do
not increase the translocation of nutrients in the plant. Further, the existing compositions do not increase ERGs in the soil. Further, the existing compositions do not increase the chlorophyll content of the plant.
Therefore, there is a need for an agricultural composition for facilitating treatment of a plant that may overcome one or more of the above-mentioned problems and/or limitations.
SUMMARY OF THE INVENTION
This summary is provided to introduce a selection of concepts in a simplified form, that are further described below in the Detailed Description. This summary is not intended to identify key features or essential features of the claimed subject
matter. Nor is this summary intended to be used to limit the claimed subject matter's scope.
Disclosed herein is an agricultural composition for facilitating treatment of a plant, in accordance with some embodiments. Accordingly, the agricultural composition may include carbanions and a diluting agent. Further, a carbanion of the
carbanions may include a carbon atom. Further, the carbon atom may include a formal charge of -1. Further, the diluting agent may be capable of dissolving the carbanions for forming a solution. Further, the dissolving of the carbanions may include
diluting the carbanions. Further, a ratio of the diluting agent to the carbanions by volume ranges from 50:1 to 550:1. Further, the dissolving facilitates at least one application of the solution to the plant.
Further disclosed herein is a method for producing an agricultural composition to facilitate treatment of a plant, in accordance with some embodiments. Accordingly, the method may include a step of extracting at least one organic material from
at least one organic material source. Further, the at least one organic material may include a carbon compound. Further, the method may include a step of blending the at least one organic material with at least one reagent for forming an agricultural
composition preform. Further, the method may include a step of applying at least one of a specific temperature and a specific pressure to the agricultural composition preform. Further, the applying initiates a chemical reaction in the agricultural
composition preform. Further, the chemical reaction may include at least one of a redox reaction and a reduction reaction. Further, the carbon compound may be reduced to form carbanions based on the at least one of the redox reaction and the reduction
reaction. Further, a carbon atom of a carbanion of the carbanions may include a formal charge of -1. Further, the method may include a step of dissolving the carbanions using a diluting agent for forming a solution. Further, the dissolving of the
carbanions may include diluting the carbanions. Further, a ratio of the diluting agent to the carbanions by volume ranges from 50:1 to 550:1. Further, the dissolving facilitates at least one application of the solution to the plant.
Both the foregoing summary and the following detailed description provide examples and are explanatory only. Accordingly, the foregoing summary and the following detailed description should not be considered to be restrictive. Further,
features or variations may be provided in addition to those set forth herein. For example, embodiments may be directed to various feature combinations and sub-combinations described in the detailed description.
BRIEF DESCRIPTION OF THE DRAWINGS
The accompanying drawings, which are incorporated in and constitute a part of this disclosure, illustrate various embodiments of the present disclosure. The drawings contain representations of various trademarks and copyrights owned by the
Applicants. In addition, the drawings may contain other marks owned by third parties and are being used for illustrative purposes only. All rights to various trademarks and copyrights represented herein, except those belonging to their respective
owners, are vested in and the property of the applicants. The applicants retain and reserve all rights in their trademarks and copyrights included herein, and grant permission to reproduce the material only in connection with reproduction of the granted
patent and for no other purpose.
Furthermore, the drawings may contain text or captions that may explain certain embodiments of the present disclosure. This text is included for illustrative, non-limiting, explanatory purposes of certain embodiments detailed in the present
disclosure.
FIG. 1 is a table listing ingredients of an agricultural composition for facilitating treatment of a plant, in accordance with some embodiments.
FIG. 2 is a flowchart of a method for producing an agricultural composition to facilitate treatment of a plant, in accordance with some embodiments.
FIG. 3 is a flowchart of a method for producing a solution of the carbanions and a diluting agent, in accordance with some embodiments
FIG. 4 is an illustration of carbanions of the agricultural composition, in accordance with some embodiments.
FIG. 5 is a plot of light scattering by the carbanions through a dynamic light scattering, in accordance with some embodiments.
FIG. 6 is a magnified view of a sample of a solution of the agricultural composition, in accordance with some embodiments.
FIG. 7 is a magnified view of a sample of the solution, in accordance with some embodiments.
FIG. 8 is a magnified view of a sample of a solution of the agricultural composition, in accordance with some embodiments.
FIG. 9 is a magnified view of a sample of the solution, in accordance with some embodiments.
FIG. 10 is a magnified view of a sample of a solution of the agricultural composition, in accordance with some embodiments.
FIG. 11 is a schematic of a carbanion of the carbanions, in accordance with some embodiments.
DETAIL DESCRIPTIONS OF THE INVENTION
As a preliminary matter, it will readily be understood by one having ordinary skill in the relevant art that the present disclosure has broad utility and application. As should be understood, any embodiment may incorporate only one or a
plurality of the above-disclosed aspects of the disclosure and may further incorporate only one or a plurality of the above-disclosed features. Furthermore, any embodiment discussed and identified as being "preferred" is considered to be part of a best
mode contemplated for carrying out the embodiments of the present disclosure. Other embodiments also may be discussed for additional illustrative purposes in providing a full and enabling disclosure. Moreover, many embodiments, such as adaptations,
variations, modifications, and equivalent arrangements, will be implicitly disclosed by the embodiments described herein and fall within the scope of the present disclosure.
Accordingly, while embodiments are described herein in detail in relation to one or more embodiments, it is to be understood that this disclosure is illustrative and exemplary of the present disclosure, and are made merely for the purposes of
providing a full and enabling disclosure. The detailed disclosure herein of one or more embodiments is not intended, nor is to be construed, to limit the scope of patent protection afforded in any claim of a patent issuing here from, which scope is to
be defined by the claims and the equivalents thereof. It is not intended that the scope of patent protection be defined by reading into any claim limitation found herein and/or issuing here from that does not explicitly appear in the claim itself.
Thus, for example, any sequence(s) and/or temporal order of steps of various processes or methods that are described herein are illustrative and not restrictive. Accordingly, it should be understood that, although steps of various processes or
methods may be shown and described as being in a sequence or temporal order, the steps of any such processes or methods are not limited to being carried out in any particular sequence or order, absent an indication otherwise. Indeed, the steps in such
processes or methods generally may be carried out in various different sequences and orders while still falling within the scope of the present disclosure. Accordingly, it is intended that the scope of patent protection is to be defined by the issued
claim(s) rather than the description set forth herein.
Additionally, it is important to note that each term used herein refers to that which an ordinary artisan would understand such term to mean based on the contextual use of such term herein. To the extent that the meaning of a term used
herein--as understood by the ordinary artisan based on the contextual use of such term--differs in any way from any particular dictionary definition of such term, it is intended that the meaning of the term as understood by the ordinary artisan should
prevail.
Furthermore, it is important to note that, as used herein, "a" and "an" each generally denotes "at least one," but does not exclude a plurality unless the contextual use dictates otherwise. When used herein to join a list of items, "or" denotes
"at least one of the items," but does not exclude a plurality of items of the list. Finally, when used herein to join a list of items, "and" denotes "all of the items of the list."
The following detailed description refers to the accompanying drawings. Wherever possible, the same reference numbers are used in the drawings and the following description to refer to the same or similar elements. While many embodiments of
the disclosure may be described, modifications, adaptations, and other implementations are possible. For example, substitutions, additions, or modifications may be made to the elements illustrated in the drawings, and the methods described herein may be
modified by substituting, reordering, or adding stages to the disclosed methods. Accordingly, the following detailed description does not limit the disclosure. Instead, the proper scope of the disclosure is defined by the claims found herein and/or
issuing here from. The present disclosure contains headers. It should be understood that these headers are used as references and are not to be construed as limiting upon the subjected matter disclosed under the header.
The present disclosure includes many aspects and features. Moreover, while many aspects and features relate to, and are described in the context of an agricultural composition for facilitating treatment of a plant, embodiments of the present
disclosure are not limited to use only in this context.
Overview
The present disclosure describes an agricultural composition for facilitating treatment of a plant. Further, the agricultural composition may include carbanions. Further, the carbanions facilitate the production of agricultural crops (plant),
translocation of nutrients in the plant, the increasing of ERGs in soil, and the increasing of chlorophyll content in the plant. Further, the carbanions facilitate remedying of soil, increasing of electrical conductivity of the soil, and recovering
fertilizer from the soil. Further, the carbanions control fungi, bacteria, viruses, and insects present on the plant. Further, the agricultural composition may be metabolic pesticides.
Further, the present disclosure describes a method for the production of the agricultural composition.
Further, the present disclosure describes PicoAg/Carbanion Agriculture (Soil Remediation, Increase Micro Siemens, Fertilizer Recovery, Crop Production, Translocation, ERGS, Chlorophyll, Crop Protection of Fungi, Bacteria, and Insects Control).
Further, the carbanions may include individual atoms. Further, the carbanions may include negatively charged carbon atoms. Further, the negatively charged carbon atom may include a formal charge of -1. Further, the negatively charged carbon
atoms may be created by making use of the physical chemistry of carbon atoms. Further, the physical chemistry may be the study of macroscopic, atomic, subatomic, and particulate phenomena in chemical systems in terms of the principles, practices, and
concepts of physics such as motion, energy, force, time, thermodynamics, quantum chemistry, statistical mechanics, analytical dynamics and chemical equilibrium. Further, the carbanions may be created by making the use of the physical chemistry of the
carbanions. Further, the physical chemistry may be the study of macroscopic, atomic, subatomic, and particulate phenomena in chemical systems in terms of the principles, practices, and concepts of physics such as motion, energy, force, time,
thermodynamics, quantum chemistry, statistical mechanics, analytical dynamics and chemical equilibrium. Further, the physical chemistry is the study of how matter behaves on a molecular and atomic level and how chemical reactions occur. Based on the
analyses, physical chemists may develop new theories, such as how complex structures are formed. Physical chemists often work closely with materials scientists to research and develop potential uses for new materials. Further, the physical chemistry
may be used in observing the assembly of molecules and determining, measuring, and quantifying the assembly of the molecules. Further, diffraction, infrared, and microscopy methods are used for observing the assembly of the molecules and further
determining, measuring, and quantifying the assembly of the molecules. Further, the physical chemistry may be used for developing better ways to measure and quantify aspects of the ingredients for developing better products. Further, physical chemistry
provides an understanding of the physical properties of atoms and molecules, the way chemical reactions work, and what these properties reveal. Further, the physical chemistry involves analyzing materials, developing methods to test and characterize the
properties of materials, developing theories about these properties, and discovering the potential use of the materials. Using sophisticated instrumentation and equipment has always been an important aspect of physical chemistry. Most physical
chemistry labs are full of analytical instruments, which may include lasers, mass spectrometers, nuclear magnetic resonance, and electron microscopes. Further, the physical chemistry may provide an understanding of chemical properties and describes the
behavior of chemicals using theories of physics and mathematical computations. Further, the properties and reactions of the chemicals may be predicted using the physical chemistry. Physical chemistry describes fundamental physical characteristics of
material be it solid, liquid, or gas. Further, the physical chemistry may be used for the development of materials, including plastics, ceramics, catalysis, electronics, fuel, batteries, surfactants, and colloids, and personal care products.
Further, the carbanions may include carbon atoms. Further, the carbon atoms may be associated with CO2 (carbon dioxide) gas. Further, an average person breathes out around 500 liters of the greenhouse gas CO2, which amounts to around 1 kg or
2.3 pounds of mass. Further, the world's population is around 6.8 billion, collectively breathing out around 2500 million tons of the CO2, which is around 7 percent of the annual CO2 tonnage churned out by the burning of fossil fuel around the world.
Further, the CO2 breath out by the average person may be a part of a natural cycle, by which the body of the average person may convert carbohydrates from CO2-absorbing plants into energy, plus water and CO2. Further, the average person may breathe the
carbon atoms of the CO2 and consume the carbon atoms of plants.
Further, the carbanions may be created using Femtotechnology. Further, the Femtotechnology is one of the most promising realms of science, bringing new products to society in many industries. Further, the Femtotechnology is only about particle
having size 1000 times smaller than a nanometer. This technology can be highly beneficial to the agricultural sector. The product is made mostly of Carbon and Nitrogen and trace elements. There are 1000 Picometers in a nanometer; an inch has
75,000,000 Picometers, and a human hair is 80,000,000 to 100,000,000 Picometers thick. Further, Femtotechnology may be described as involving the alteration of the structure and the chemical properties of individual atoms through the manipulation of
energy states of electrons within the individual atoms to produce states with unusual properties, producing some form of exotic atoms. Further, the Femtotechnology may allow the usage of atoms singularly. Further, the Femtotechnology may be used for
the fabrication of structures where atoms may be positioned with sub-nanometer accuracy. This may be important where interaction with a single atom or molecule may be desired. Further, the Femtotechnology may be used for altering electron distributions
around atoms to promote surface energy to achieve inhibited infection without potential nanomaterial toxicity concerns. Further, the Femtotechnology may be used to describe the control of electron distribution around the atoms to provide desirable
properties. Further, the control of the electron distribution may greatly change surface energy and, thus, the way that proteins adsorb onto a material. Further, the excitement or rearrangement of electrons around the atoms may influence many cellular
functions including cell movement, intracellular transport to organelles, adhesion, growth, and ECM formation. Further, the Femtotechnology may control cellular microtubules (MTs). MTs are cylindrical cellular formations 25 nm in diameter, and they are
made out of tubulins. Dynamic instability due to MT plus end-binding proteins also called "plus end-tracking proteins", are able to "surf" the dynamic ends of the MTs. Further, when tips are expressed as green fluorescent proteins, the fluorescence is
the brightest at the MT and decreases in intensity toward the minus end of the MT, forming a comet tail. Further, external stimulation is used to excite the MT and end-binding proteins to promote the movement of cells using the Femtotechnology. This
may be a less toxic manner through which to alter surface energy to increase tissue growth since electron distributions may be changed for numerous macro-, micro-, or nanomaterials. Further, the Femtotechnology may be used to reduce the toxicity in any
macro-, micro-, or nanomaterials by exciting electrons. The change in electron distribution, along with the associated charge redistribution, may alter surface energetics to change the adsorption of certain proteins (as well as cellular functions).
Further, the carbanions may be created using Femto-technology. Further, the Femto-technology may be used for creating 8-octet, 9-nonet, 10-dectet, 11-undectet, and 12-duodectet by addition of electron on a carbon atom. Further, the
Femto-technology may be used for matter manipulation for modifying the carbon atom.
Further, the carbanions produce tillering in agricultural crops for facilitating the agricultural crop production. Further, an increase in crop production may be caused by tillering. Further, the tillering may increase crop production by 100%. Further, the increase in crop production is a result of translocation that is created by the negatively charged carbon atom having a configuration of 6 protons, 6 neutrons, and 8 electrons. Further, the carbanions mobilize nutrients by fracturing the
nutrients for facilitating the translocation into plants (agricultural crops). Further, the carbanions increase ERGs in the soil. Further, ERGs may be associated with Soil Energy. Further, higher ERGs increase nutrients intake rates from the soil to
plants.
Further, the present disclosure describes the carbanions for facilitating increasing the production of the agricultural crops (plants). Further, the carbanions may facilitate tillering in the agricultural crops. Further, the tillering may
include getting more than one "Plant" or "Shoot" from a seed of a plant. Further, the capability of getting more than one "Plant", "Branches" "Head Rows" "Buds" "Root Mass" or "Shoot" from the seed is also known as "tillering". Further, the tillering
may be found in grass crops that have meristematic tissue above each node. These active growth sites can produce another stem (tiller) under the right conditions. Dicots such as soybean do not have the same type of meristems at their nodes so they do
not produce more stems or tillers. Rather they have the capability of making branches at the nodes. Branches and tillers have a similar function which is to provide more leaf areas under good growing conditions and the sites for more fruit production.
Further, the tillers are produced when the amount of photosynthate (sugar) produced by the plant photosynthesis exceeds the amount of energy required to maintain plant function. In other words, when the plant is producing lots of energy and does not
require nearly that much energy to maintain its growth it then makes a tiller. So tillering is a sign of a healthy, actively growing plant that has lots of sunlight, plenty of nutrients, and cool evening temperatures. Further, the carbanions may
trigger the tillering that may not be traditional tillering but better plant performance and nutrient uptake which caused the plants to grow better resulting in multiple tillers that are normally not achieved. Further, the tillering may be dependent on
hormonal regulation (auxin, cytokinins, and gibberellins) as influenced by certain nutrients balances (Mn, Cu, Zn, Fe, etc.). Further, the tillering may make Christmas trees grow to 6 feet in just 2.5 years instead of 5 years. Further, Corn tillering
may increase the growth of the corn up to 15 to 30 more bushels per acre. Further, the corn tillering may produce 15 bu (bushels) more per acre. Further, the corn tillering may produce 30 bu more per acre. Further, more tillering and more height
corresponds to the increased production of sugar cane. Further, nitrogen management is key for getting maximum output when growing crops (agricultural crops).
Further, the carbanions may be individual atoms or atoms in covalent bonds. Further, the individual atoms alone or the atoms in the covalent bonds may create powerful electromechanical reactions to disassemble organic material, one atom per
atom at a time. Further, the individual atoms alone or the atoms in the covalent bond may work on the fungi, the bacteria, or the viruses to eliminate the fungi, the bacteria, or the viruses.
Further, the carbanions increase Brix levels by 80% in 3 hours and maintained a higher Brix level than untreated for 20 days. Further, the plant may develop frost tolerance. Further, the carbanions performed soil remediation and made old
fertilizers available, and mellowed the soil. Further, the carbanions may increase the electrical conductivity (micro Siemens) (EC) of the soil and ERGs in the soil.
Further, a single application of the carbanions may increase electrical conductivity (micro Siemens) levels of the soil by 10%. Further, the carbanions may be configured for rising electrical conductivity of soil about 10% based on dispensing
the carbanions in the soil. Further, a solution of the carbanions may moisten the soil for facilitating the dispensing. Further, the carbanions may simulate soil electrical conductivity response. Further, higher electrical conductivity enables more
active nutrient transfer from soil to crops. Further, 60 milliliters of the solution are added to 500 grams of moist topsoil in a Ziplock bag. The soil was mixed, then stored for 12 hours to become uniform in moisture by capillary action. Soil treated
with either a 1:100 or 1:400 ratio of the solution in water averaged about 10% higher in electrical conductivity than soil moistened with distilled water. Further, the carbanions may raise the electrical conductivity of the ammonium sulphate solution.
Further, the carbanions produce a maximum 28% rise in the electrical conductivity of the ammonium sulphate solution with a 1:100 solution of the carbanions. Further, the carbanions may raise the electrical conductivity of the urea solution. Further,
the carbanions produce a maximum 28% rise in the electrical conductivity of the urea solution with a 1:100 solution of the carbanions.
Further, the present disclosure describes femto-products comprising the carbanions. Further, the femto-products comprising the carbanions may have the following characteristics:
1). No harm to air (no GWC, ODC, VOHAP, or VOC) soil, or water.
2). cannot be made of organic chemistry, graphene, or nanotechnology, just single atom Picotechnology or physical chemistry
3). The goals are primary distribution as an OTC product.
4). It must be made of atomic elements and not molecules.
5). Must be able to kill all pests, be it bacteria, fungi, viruses, and insects.
6). Must be able to deep clean and grow skin and heal wounds just days not weeks
7). Must be able to penetrate the shields of all pests.
8). Must be approved at the State and or Federal FDA or better be exempt.
9). Must be safe for humans, bees, birds, and animals--zero side effects.
10). Must be made of 100% new organic carbon.
11). No Chemicals
12). No Biologicals
13). No Nanotechnology
14). No Graphene
15). No Molecules
16). Eliminate Sickness
Further, the femto-products may be formed using the physical chemistry. Further, the femto-products may 89% Biobased Content. Further, the femto-products may include ingredients such as EAFUS: Food Additives. Further, the femto-products may
restructure water, and spray rig pressure drops by 19%. Further, the femto-products may increase Brix levels from 100% to 200%. Further, the femto-products may increase the Electrical Conductivity (EC) (micro Siemens) of the soil. Further, the
femto-products may increase carbon dioxide consumption. Further, the femto-products may increases ERGS by 2000%. Further, the femto-products may increase Corn, Soybeans, Wheat, Oats, Alfalfa production. Further, the femto-products may provide a spray rig
cleaning benefit. Further, the femto-products may provide wind resistance benefits. Further, the femto-products may provide late planting benefits. Further, the femto-products may provide frost resistance. Further, the femto-products may increase 269%
Brix in macadamia benefit. Further, the femto-products may stimulate crop production factors. Further, the femto-products don't affect good bacteria. Further, the femto-products may achieve "increasing carbon dioxide consumption". Further, the
femto-products may be used as seed wash, germ test 85% untreated to 98% treated. Further, the femto-products may provide tank mixing, water restructuring, lower dynes from 70 to 30. Further, the femto-products may be used for both organic fertilizer &
organic pesticides. Further, the femto-products may not pose any health hazards signage to workers, customers, or owners. Further, the femto-products may not require the posting of warnings signs anymore posted to protect customers or workers when
spraying or applying the femto-product. Further, the femto-products may not pose any concerns about toxic chemical sprays drifting into neighborhoods or runoff into water or air supply. Further, the femto-products may not pose any concerns over issues
associated with registered pesticides when spraying. Further, the femto-products may not require a protected storage area or special handling of dangerous chemicals. Further, the femto-products may not require any special handling, transportation, or
equipment. Further, the femto-products may not pose any threat or concern over fees and fines levied by OSHA guidelines. Further, the femto-products may not require any hazardous waste disposal requirements to follow. Further, the femto-products may not
invite workmen's compensation claims or lawsuits from customers or workers claiming insecticide exposure. Further, the femto-products may not invite workers compensation fees charged after receiving a waiver for reducing or eliminating pesticides and
toxic cleaners. Further, the femto-products may not provide any liability for pollution mitigated for land sales, no cleanup of pesticides. Further, the femto-products may not require any additional labor or costs required for associated spraying and
handling. Further, the femto-products may provide a "poison-free" working environment by replacing dangerous fungicides and insecticides, in multiple forms, plus degreaser, toxic detergents, numerous cleaners, and solvents. Further, the femto-products
may reduce pesticide and chemical costs by up to 75%. Further, the femto-products may enhance plant root growth and nourishment by breaking the surface tension of water for deeper and more rapid soil penetration. Further, a yield of 105% to 300% of the
product is obtained by using the femto-products. Further, the femto-products may appear to strengthen the plant, which provides stronger blooms and increases systemic acquired resistance, defending plants from insects and fungus. Further, the
femto-products may increase plant growth by 10% to 300% over a 3-month period of time for starter plants. Further, the femto-products may save 3,000 to 5,000 annually by reducing discarded plants in a nursery. Further, the femto-products may be a
non-toxic product that can be recommended and sold to customers and other growers. Further, the femto-products provides increased peace of mind about crop success and non-poisonous operations at reduced costs. Further, the femto-products may facilitate
faster crop production and more turnover of crops in fields. Further, the femto-products may facilitate a 15% increase in greenhouses and possibly a 100% increase in annual field production by growing an extra crop per annum. Further, faster crops mean
less borrowing costs on crop loans. Further, the femto-products may be alternated, rotated, or mixed with chemicals to lower costs and reduce environmental pollution and worker safety. Further, the femto-products may be used for washing hands, cleaning
tools, therefore not spreading diseases from plant to plant or tree to tree or human to customer. Further, 120-day rice crops grown in 100 days with up to 45% yield increase, 120-day onion crop grown in 90 days with 30% more products based on an
application of the femto-products. Further, the femto-products may increase the quality of grains and nutrients of crops grown. Further, the femto-products may decrease the plum harvest rejection rate from 65% to only 35%. Further, the quality of fruit
and skin now meets the shipping standards. Further, the femto-products may be made from 100% US GOV Food and Drug Administration (FDA) EAFUS food additives. Further, the femto-products may be defined as food by the FDA. Further, the femto-products may
improve the plant's electro-mechanical function, which enables cells to communicate more efficiently and be more productive. Further, the femto-products may increase plant Brix/sugar levels by up to 100%. Further, the femto-products may be used to supply
nutrients to seeds which encourage germination and vigorous growth. Further, plants sprayed with the femto-products reduce CO.sub.2 from the atmosphere by up to 33% in comparison to regular plants by increasing plant sugar levels in the photosynthesis
process. Further, the femto-products may produce potential benefits such as claimed carbon credits that help to reduce the price of PicoAg.TM. (femto-products). Further, the femto-products may be nontoxic, non-hazardous, cost-effective, and humanly safe. Further, the femto-products may reduce hunger, starvation, and poverty with increased production.
Further, the femto-products may include a "PicoAg 4nl 25B". Further, the femto-products may be a biopesticide. Further, the femto-products may control bacteria, insects, fungi, and viruses. Further, the femto-products may be created using Pico
technology.
Further, the femto-products qualifies as a Biopesticide, Biostimulant, and Biofertilizer.
Further, the femto-products may be used for the elimination of vital elements in bacteria, insects, fungi, and viruses.
Further, the femto-products is configured for eliminating the cell membrane of the bacteria and puncturing the cell membrane. Further, the eliminating and the puncturing of the cell membrane may drain proteins and lipids from the bacteria.
Further, the femto-products is configured for eliminating the cellulose and chitin of the fungus.
Further, the femto-products is configured for eliminating strands of a nucleic acid of the virus, either DNA or RNA of the virus, and protective protein coat of the virus (the capsid), or a lipid envelope of the virus, surrounding the protein of
the virus.
Further, the femto-products is configured for dissolving cellular membranes of the insects, eliminating cells desiccation of the insects, eliminating or penetrating cellular metabolism of the insects, dissolving cuticles of the insects,
eliminating lubrication joints of the insects leading to paralysis, stripping the protective shields of the insects, eliminating exoskeleton structure of the insects, and dissolving chitin and protein substances of the insects.
Further, the femto-products immediately impacts the exoskeleton structure of the pest upon contact by disrupting the molecular structure of the chitin and other protein substances that protect the insect. This mechanism of action triggers the
rapid and irreversible deterioration of the insect's spiracles and tracheal system, resulting in suffocation. Further, the femto-products kills insects with the elimination of chitin. Further, the chitin is a polysaccharide and a carbohydrate that has a
chain of sugar molecules. Further, chitin has a structure like cellulose. Additionally, the chitin may be present in the exoskeletons of the insects.
Further, the femto-products benefit from the revolutionary method of insect control with an absence of undesirable side effects on human health and no harm to the ecosystem. Additionally, unlike standard insecticides in use today, no built-in
resistance may be developed by the targeted insects.
Further, the femto-products may be mechanical in primary sequential steps. Further, a first step is a direct interaction between the surface and the outer membrane of the pests, causing the membrane to rupture and leak fluids, proteins, and
nutrients.
Further, the femto-products may attack pests at the atom level. Further, at the atom level, the shield of the pests starts to disassemble. Further, the femto-products kills the pests by eliminating the shield.
Lastly, in a few more ways, the femto-products' electromechanical effect may affect the pests: There may be a second step related to the holes in the outer membrane, through which the pests lose vital nutrients, protein, water, and components,
causing a general weakening of the pests. Electromechanical effect of the femto-products may affect pests, the femto-products penetrates and dissolves lipid of cellular membranes of the pests. This causes cell desiccation to leak water, proteins, and
nutrients and collapse. By interfering with cellular metabolism during metamorphosis. By dissolving cuticles, the lubrication in the insect and joints of the insects, leading to paralysis. By stripping the pests' protective shields (wax, biofilm,
etc.), rendering the pests defenseless against subsequent treatment. The extracts impact the exoskeleton structure of the pests upon contact by disrupting the molecular structure of the chitin and other protein substances that protect the insect. The
extracts may have the ability to penetrate complex hydrocarbon chains and disintegrate the insects. The change in the environment for growth with PH from acidophils and neutrophils to alkaliphiles.
Further, the femto-products may be configured for punching holes in a cell of the pests. Further, the punching of the holes in the cell breaches a main defense of the cell. Further, an unopposed stream of the femto-products enters the cell.
This puts several vital processes inside the cell in danger. Further, the femto-products overwhelm the inside of the cell and obstruct cell metabolism (i.e., the biochemical reactions needed for life). Further, the femto-products bind to enzymes of the
cell halting the activity of the cell. Further, the pests no longer "breathe", "eat", "digest", "reproduce" or "exist".
Further, an outer membrane of the cell, including that of a single cell organism like pests, is characterized by a stable electrical micro-current. This is often called "transmembrane potential", and is literally, a voltage difference between
the inside and the outside of a cell. It is strongly suspected that when a pest comes in contact with the femto-products, short-circuiting of the current in the cell membrane may occur. Further, the current weakens the outer membrane and creates holes
for leaking water, proteins, and nutrients from the cell.
Further, the femto-products effects fast and affect such a wide range of pests. The experiences observed explain the speed with which pests and other pests perish on femto-products surfaces by the multi-targeted effects. Further, membrane
perforation may inhibit any given enzyme that "stands in its way," and stops the cell from transporting or digesting nutrients, repairing its damaged membrane, and breathing or multiplying. This makes the pest harmless to humans, birds, and animals.
This has no side effects or harm on human, birds, and animal health. These solutions do not harm mammal cells nor do the solutions attack the neurological systems of humans, birds, and animals. Further, the femto-products may lyse cells to extract
protein or organelles, or to permeabilize the membranes of living cells.
The femto-products dissolves lipids from cell membranes making the cell membranes permeable to antibodies. Because the organic solvents also coagulate proteins, the femto-products may be used to fix and permeabilize cells at the same time.
Saponin interacts with membrane cholesterol, selectively removing it and leaving holes in the membrane. Permeabilization is the process of making something, such as a membrane or cell wall, permeable. Lyse is a verb referring to the process of lysis,
the death of a cell. Lysis refers to the breaking down of the membrane of a cell, often by viral, enzymic, or osmotic mechanisms that compromise cell integrity. A fluid containing the contents of lysed cells is called a lysate. In molecular biology,
biochemistry, and cell biology laboratories, cell cultures may be subjected to lysis in the process of purifying the components, as protein purification, DNA extraction, RNA extraction, or purifying organelles.
Trophobiosis Cycle: Pesticides weaken plants. Weakened plants open the door to pests and disease. Further, the pesticides precipitate pest attacks and disease susceptibility, and thus the pesticides induce a cycle of further pesticide use.
Further, the femto-products may include an agriculture Product "PicoAG 4-N-1". Further, the agriculture Product "PicoAG 4-N-1" may be made of only atoms 1000 times smaller than nanometer and made of Femto-technology (Electrons, Protons,
Neutrons) elements.
Further, the femto-products may include PicoAg. Further, the PicoAg may facilitate the tillering for increasing the production of the agricultural crop. Further, the PicoAg may replace Ag Pesticides, Ag Fertilizer, Ag Remediation, and Ag
Production with No Side Effects with a single product of atoms 100% organic matter.
Further, 2 applications of the PicoAg at a rate of 1.5 oz. (S2.00 US Dollars) per 16 liters of water (7 spray loads/application) is applied to the sugarcane. Further, a Sugarcane Farm Sprayed with the PicoAg may provide relatively uniform
growth of the sugarcane in height and size, increase in no. of tillers to 12-15 tillers per hill, and increase in a height of the sugarcane to 5 ft. and 6 inches, reduction in pests Infestation none. Further, the tillering was increased on PicoAg
treated plants by 250% compared to normal plants. Further, the PicoAg may be applied to a palm tree. Further, 1 application of the PicoAg at a rate of 1.5 oz. (2.00 US Dollars) per 16 liters of water (7 spray Loads/application) may be applied to the
palm tree. Further, the PicoAg increases the height and size of the palm tree. The leaves of the palm trees are larger and exhibited a shiny green appearance.
The use of PicoAg is all about timing. If the timing is off, the production may be less. Further, the PicoAg can be used from 1 to 7 times. 97% of the farmers only use the PicoAg for Planting and Herbicide Passes. Further, the PicoAg can be
used by farmers at BURNDOWN Herbicide pass and it is recommended to add AMS to kill Weed. The other benefits of the BURNDOWN usage are Spray Rig Cleaning and EC Soil Remediation. The PicoAg may mobilize the tied up nutrients from chelation. Further,
the PicoAg can be used with a liquid at 3 oz. per acre with 10 gallons of water at seed planting in seed furrow or 2.times.2. Further, the PicoAg may be sprayed to the plant at the 3 leaf stage of the plant. Further, 5 oz. of the PicoAg per acre with
10 gallons of water per acre is sprayed to the plant. Further, the PicoAg can be used with Herbicide pass and it is recommended to add AMS to kill a weed. The PicoAg can be used last time 20 days passed Herbicide Pass to push the crops. The PicoAg has
been used for extending the time a plant can grow. The PicoAg has been used for Frost protection on Corn, Soybeans, Tobacco, and Tomato.
Further, the PicoAg helps plant nutrient availability by fracturing and mobilization of tied up plant nutrients. Further, the mechanism for increased production may include soap ingredients acting as a vehicle for plant nutrient entry and
assimilation. Further, the PicoAg may be configured for getting nutrients into the plants through the back door. Further, the PicoAg releases metal ions from their attachment sites. Further, the PicoAg blended in a water solution with chelated trace
elements increases the availability of those traces to crops when foliar-applied on crops. Further, the PicoAg greatly reduces the surface tension of water, which improves leaf contact and enhances the internal translocation of nutrients through crop
xylem and phloem systems. The PicoAg is also a solvent that softens the waxy cuticle on leaves so nutrients can easily enter plant circulation pathways. All ingredients in the PicoAg are derived from plants, so crops readily absorb and metabolize the
PicoAg. Very small amounts of the PicoAg are needed to "amplify" foliar sprays just four or five ounces per acre.
Further, the PicoAg may add energy, and organic nitrogen to the plants without losing, leaching, or burning up the soil carbon. Further, adding 2 mL of the PicoAg in a ratio [500:1] to the soil increase the ERGs of the soil up to 1800.
Further, the PicoAg increases the chlorophyll in the plants. Further, the increase in the chlorophyll has all kinds of benefits like a less fertilizer requirement after planting of the plant. Further, the PicoAg may be a Non-GMO organic plant
biostimulant resulting in enhanced quantity and higher nutrient density quality production of all agricultural major crops. Further, PicoAg is a unique and powerful agro-input capable of enhancing the health of plants & increase crop yield. It's a
Non-GMO and organic product made of plant extracts. It dramatically boosts production in any soil, any region, and works in all kinds of Crops and vegetables. This eliminates the health hazards for farmers and consumers. Further, the PicoAg may
provide shorter and higher plant germination time, increased growth, more yield, and improves disease and pest resistance. The PicoAg is made of the highest grade of food ingredients. Further, the PicoAg may increase yield ranging from 40%-300% in
agricultural crops and vegetables. The PicoAg does not contain any toxic or hazardous components, hormones, chemicals, pesticides, any synthetic material, and is safe for all plants, humans, and animals. It is non-carcinogenic.
The PicoAg has been proven to be effective at 16,000 to 1 and as high as 32,000 to 1 dilution. The Elements can be both an organic cation-anion separator as well as a cation-anion translocator to feed plants and it can increase the Brix levels
in plants, which increases CO2 consumption that gives life to plants. It is not toxic organic chemistry, it's the traditional sustainable nutrient for plants, and there are no residuals to harm the environment, oceans, humans, animals, birds, or living
creatures. It's also the best technology for soil and water remediation mobilizing chelated immobilized tied up nutrients. This is Photosynthesis without an increase in CO2 Consumption.
Further, the PicoAg possesses a unique ability to substantially increase the level of sugar production within the leaves of a plant to a great extent. This, in turn, acts to accelerate the function of photosynthesis with the result that the
treated plant becomes healthier, more disease-resistant, and faster growing. This results in larger crop yield and quality output. The germinating seed produces an embryonic root (radical) that grows into the soil, in response to the earth's
gravitational field. As new cells are added, the root elongates producing hair roots and lateral roots. The roots remain interconnected, producing a network of living cells throughout the soil. Within the root, the inner cells become specialized to
conduct solutes (water+substances dissolved in it) from the root to the shoot (via xylem) and from the shoot to the root (via phloem). Flow from the shoot to the root is achieved by loading sugars produced in the leaves into the phloem. The sugar-laden
solute moves downward, to the sites of lower concentration in the root. The xylem, carrying solute from the roots to the shoot, acts like a bundle of capillary tubes, supporting the water in a vertical reservoir. The leaves of the plant actively lose
water through pores at the surface (transpiration), drawing the water in the xylem upwards. By this method, essential nutrients extracted from the soil are transported to sites of growth and production in the shoot. The surface of the leaf is
specialized for trapping energy from light (photosynthesis) and storing it as sugars and starch. Therefore the upper leaf surface must be angled to face the sun, which causes its surface temperature to rise 10 degrees C. above the ambient air
temperature. To control water loss, most leaves have a thick water resilient waxy layer. The specialized openings that control the rate of water loss (stomata) tend to be more numerous on the underside of the leaf. Accordingly, leaves are not adapted
for taking up nutrients. It's the mass flow of solutes from the soil to the roots that provide the greatest amount of nutrients for plants. Further, the PicoAg acts to stimulate new growth and development when applied to bare root stock before
planting, or saturating the root structure when in place. It dissolves NPK from the roots, thereby enhancing nutrient uptake into the plant. Nutrient uptake is expedited from the inclusion of sodium within the formulation. Sodium is a cation, which is
an atom or group of atoms carrying a positive electric charge. The positive charge results because there are more protons than electrons in the cation. The negatively charged anions are attracted to the positive sodium cation, attach themselves, and
hitch a ride into the plant. In other words, NA+ is a Sodium Transporter conveying nourishment directly to the plant. The reason for this nutrient effect is the minuscule size of the molecules, which allows them to enter the plant cells (in the
leaves), where the sugar factory is located. This causes a maximized increase in photosynthesis, which is the basis for the starches, cellulose, waxes, carbohydrates, oils, and protein that are the building blocks for all plant growth. Perhaps an
equally powerful stimulant to plant growth occurs when nutrition is provided directly to the leaves, through the stomata using the foliar feed. In the early morning hours, or later in the afternoon, when the ambient air temperature falls below that of
the ground temperature, the stomata will open and make themselves susceptible and amenable to the uptake of fluids and nutrients. Due to the Pico sized particles that comprise the PicoAg, they are able to easily enter the stomata of the leaves, where
their beneficial effect can be more directly accepted by the plant. Therefore, it is highly suggested that in order to maximize the nutritional boost possible from the spraying of the PicoAg, the leaves be sprayed both from above and below, as per the
application protocol. The plants sprayed with the PicoAg appear to grow more swiftly, be healthier and bear larger crops, the only explanation is that this could only be attributed to an increase in the level of photosynthesis within the leaves.
Further, the PicoAg may increase the sugar content of the leaves increased by a factor of slightly more than 50%, within seven days of spraying, compared with neighboring plants that were not sprayed. What was even more interesting was that so long as
the plants were sprayed at 7 or 10-day cycles, the sugar content remained at an increased constant 50%+ level. Once spraying was discontinued, the sugar level returned to normal after about four to five weeks, indicating a direct correlation between the
application and non-application of the spray. In addition to being stronger and more disease resistant, the crop can be expected to be larger, and very often the size of the individual fruit, nut, flower, etc. will be significantly greater. The
healthier plants also appear to be less prone to fungal or bacterial disease and to be much more pest resistant. This appears to confirm the field reports that there are significantly larger crops and fruit size when compared with the previous years of
normal farming practice.
Further, the PicoAg increases the electrical conductivity (micro Siemens) of the soil. Further, the PicoAg replaces 300 lbs. of fertilizers with 8 oz. of the PicoAg. Further, 1 cubic inch of the PicoAg can be spread to an 11.9 Acre of
surface area at 1 nanometer thick, where 1 square inch has 5400 trillion Picometers. This large surface area of colloids, and their highly energetic reaction due to their small size, makes the PicoAg highly effective in carrying other blended products
into plant leaves (such as herbicides or foliar nutrients) and transporting nutrients through the plant's circulatory system. Below 50 nanometers, normal chemical reactions are dramatically changed. This gives materials surprising new properties. When
reduced to "Nano" size, a red compound may appear green. All molecules have a positive or negative electrical charge. Thus all living cells are electromagnetic. Plant growth and nutrient exchange occur with "biological ionization," or transfer of
ions. Electrical charges and magnetism have an impact on how molecules behave. In conventional PicoAg 25B, two positive poles of a magnet repel one another, and a positive and negative pole attract each other. However, when molecules are refined to
the Pico level, positive molecules attract other positive molecules. This only happens at the pico-scale size. Plants, humans, and animals in essence are electromagnetic and are governed by the Periodic Law and table. In photosynthesis, plants require
the radiation from the sun plus six molecules of water and six molecules of carbon dioxide to make one basic sugar molecule and six molecules of oxygen. The plants give off oxygen into the atmosphere during photosynthesis. The plants use a molecule of
basic sugar manufactured as the foundational building block for roots, stems, leaves, and fruit or grain. Further, the basic sugar molecule is important in the whole equation of plant growth. Further, increasing the production of sugar and other
dissolved solids in plants may have a major impact on plant production and quality. The percentage of sugars and dissolved solids in plant solution is referred to as a "Brix" reading. The PicoAg is able to enter into the plant's cells due to its very
small Pico atoms size. Although it doesn't have large amounts of nutrients normally expected of foliar fertilizers, its pico-sized colloids are able to diffuse into the plant cells, increasing sugar production. When the PicoAg is applied early in a
plant's germination and rooting stage, such as the two-leaf stage of corn and soybeans, translocation of leaf sugars to the root generates more exudates from new roots. Soil organisms respond by converting more nutrients in the soil. The resulting
larger root system helps crops keep growing through dry periods during the season. We've seen the largest yield differences in regions and seasons where moisture is limited, or soil has low organic matter. Sodium molecules which are cations (positively
charged molecules) make up a sizeable amount of the Adjuvant product. These cations increase electrical conductivity in the nutrient solutions circulating in the crop's xylem and phloem circulation system. The basic photosynthesis process described
above is often written as this formula: 6CO2+6H2O+Sunlight=C6H12O2+6O2
In effect, carbon dioxide and water plus energy may form simple sugar and release oxygen into the atmosphere. But the secondary reactions of photosynthesis are far more complex in the plant. In the chloroplasts of the cells sugar factory, four
positive magnesium molecules combine with one nitrogen molecule. Nanoscale sodium molecules are attracted to these positive magnesium molecules. Other elements that are chelated (attached) to the sodium also are translocated into the sugar-factory
cell. The PicoAg has a strong surfactant effect, which means that the surface tension of water is greatly reduced. Water is "wetter." Within a plant, this apparently reduces the necessary osmotic pressure needed to move nutrient solutions through the
crop, between leaves to roots. The net result of the enhanced nutrient transfer is more fuel, energy, and conductivity to boost the sugar-making efficiency of photosynthesis. Further, the PicoAg trials have increased the sugar levels of fruit on a
variety of plants. Yield results are most pronounced where normal plant nutrition or moisture is limited. When this higher level of sugars and dissolved solids is achieved, plant production and crop quality increase. Higher nutrient levels in a crop
are good. This means the plant has a greater natural ability to defend itself from attacks from pathogens, as a result of having a good supply of nutrients and a high sugar level. The overall effects of using the PicoAg mean that growers achieve
benefits by producing healthier, more nutritious food for humans and animals. In high-organic soil and perfect growing seasons, the yield increase may be moderate, but other benefits such as crop quality and resistance to lodging help pay for the
application. In stressful seasons or difficult soil, growers report yield increases as high as 33%, with greater plant health. The PicoAg increases the electrical conductivity (micro Siemens) of the soil to loosen the soil. Future agricultural
strategies may also include the use of Picotechnology instead of nanotechnology to reduce the toxicity since electrons can be excited in any macro-, micro-, or nanomaterials. The change in electron distribution, along with the associated charge
redistribution, can alter surface energetics to change the adsorption of certain proteins (as well as cellular functions).
Further, (TPH) are hydrocarbons that exist in crude oil, which is used to make petroleum products. TPH is a family containing hundreds of chemical compounds that were originally derived from crude oil so it is often referred to as hydrocarbon
oil, mineral oil, and grease. Further, the hydrocarbons are molecules that include hydrogen and carbon atoms. Hydrocarbon examples in everyday life include paraffin and isopropyl alcohol. Once formed, hydrocarbons combine easily with other atoms to
create organic compounds. TPH are mixtures of chemicals that are mainly made from hydrocarbons. Examples of chemicals found in TRPH include Hexane, Benzene, Toluene, Xylene, Naphthalene, Fluorene, and Components of gasoline, mineral oils, and other
petroleum products. It would be impractical to measure the full scope of TPHs present at a given site, but obtaining a composite amount of TPH found in a sample can help identify the extent of the contamination. These hundreds of components can be
divided into groups, known as petroleum hydrocarbon fractions, based on how they act in soil and water. These petroleum hydrocarbon fractions allow scientists at Phoslab Environmental Laboratories to measure the concentrations of TPH. Further, the TPH
is released into the environment through accident-prone leakages from industries and as byproducts from commercial or private uses. Total petroleum hydrocarbons in water typically show up in the form of a thin surface film, while heavier fractions might
appear as sediment at the bottom of the waterbed. Total petroleum hydrocarbons in soil may become absorbed by groundwater. Everyone is exposed to some amount of TPH; components are airborne. Prolonged exposure, however, is dangerous and poses a threat
of contamination of the TPH. Certain occupations such as those involved in extracting and refining crude oil face a more significant risk through inhalation of airborne contaminants and skin contact. Underground contamination such as from a leaking
storage tank can expose others through drinking water and contact with ground soil. To minimize contamination, Phoslab Environmental uses state-of-the-art technology to test a wide variety of samples to accurately measure the TPH concentration in air,
water, or soil. While most people inhale and exhale petroleum hydrocarbons on a daily basis, prolonged exposure can lead to any number of health complications. Reported TPH health effects include Headaches, Dizziness, Peripheral neuropathy, Irritation
of skin, and eyes, Permanent damage to liver, kidneys, and lungs, and Complications in pregnancy. Health risks vary depending on the length of the exposure and the toxicity of individual TPH compounds. In some cases, exposure can be deadly. Further,
Pico-Clean comprising the carbanions is configured for removing TRPH (o-Terpheny C18H14 & n-Triacontane C30H62) 99.997%, except for 38 Mg/Kg/9680 Mg/Kg=only 0.00392562%. Further, Pico-Clean may be configured for Oil and Starch Remediation.
FIG. 1 is a table 100 listing ingredients of an agricultural composition for facilitating treatment of a plant, in accordance with some embodiments. Further, the table 100 may include a column 102 and two rows 104-106. Further, the table 100
may include two cells (column 102, row 104) and (column 102, row 106). Further, the agricultural composition may include carbanions and a diluting agent.
Further, a cell (column 102, row 104) of the table 100 may be related to the carbanions. Further, a carbanion of the carbanions may include a carbon atom. Further, the carbon atom may include a formal charge of -1.
Further, a cell (column 102, row 106) of the table 100 may be related to the diluting agent. Further, the diluting agent may include water. Further, the diluting agent may include a solvent. Further, the diluting agent may be capable of
dissolving the carbanions for forming a solution. Further, the dissolving of the carbanions may include diluting the carbanions. Further, a ratio of the diluting agent to the carbanions by volume ranges from 50:1 to 550:1. Further, the dissolving
facilitates at least one application of the solution to the plant. Further, the diluting agent may include water. Further, the plant may include at least one agricultural crop. Further, the at least one application may include spraying, dispensing,
etc. Further, the at least one application may include an in-furrow application, a foliar application, etc. Further, the solution may be applied to the plant in at least one vegetative state of the plant.
Further, in some embodiments, the ratio of the diluting agent to the carbanions by the volume may be 375:1.
Further, in some embodiments, the ratio of the diluting agent to the carbanions by the volume may be 533:1.
Further, in some embodiments, the ratio of the diluting agent to the carbanions by the volume may be 320:1.
Further, in some embodiments, the ratio of the diluting agent to the carbanions by the volume may be 400:1.
Further, in some embodiments, the carbanions are derived from at least one organic material. Further, the at least one organic material may be associated with at least one plant. Further, the at least one organic material may be 100% biomass.
Further, in some embodiments, the carbon atom may be associated with a hybridization state. Further, the hybridization state may be sp3 hybridization state. Further, the carbon atom in the sp3 hybridization state may be trivalent. Further,
the carbon atom in the sp3 hybridization state may include a lone pair of electrons on the carbon atom. Further, the carbon atom in the sp3 hybridization state forms three single bonds.
Further, in some embodiments, the solution may include a dispersing agent capable of dispersing the carbanions in the diluting agent. Further, the carbanions are present in the solution in a form of granules. Further, a size of a granule of
the granules may be 340 pm (picometer).
In further embodiments, the agricultural composition may include a chelating agent capable of chelating at least one nutrient associated with the plant. Further, the solution may be capable of mobilizing the at least one nutrient from the
chelating agent to the plant based on the at least one application of the solution to the plant. Further, the at least one nutrient may include a micronutrient, a macronutrient, etc. Further, the at least one nutrient may include Mn (manganese), Cu
(copper), Zn (zinc), Fe (iron), etc.
Further, in some embodiments, the solution may include a surface tension reducing agent capable of reducing a surface tension of water associated with the plant. Further, the solution may be capable of enhancing an internal translocation of at
least one nutrient associated with the plant through at least one of a xylem system and a phloem system of the plant based on the reducing. Further, the at least one nutrient may include a micronutrient, a macronutrient, etc. Further, the at least one
nutrient may include Mn (manganese), Cu (copper), Zn (zinc), Fe (iron), etc.
Further, in some embodiments, the solution may include a solvent agent capable of softening a surface of at least one part of the plant based on the at least one application of the solution to the plant. Further, the at least one part of the
plant may include leaves. Further, the solvent agent softens a waxy cuticle disposed on the surface of the leaves based on the at least one application. Further, at least one nutrient enters into at least one circulation pathway of the plant through
the surface of the at least one part of the plant based on the softening. Further, the at least one nutrient may include a micronutrient, a macronutrient, etc. Further, the at least one nutrient may include Mn (manganese), Cu (copper), Zn (zinc), Fe
(iron), etc.
Further, in some embodiments, each carbanion of the carbanions may be capable of creating an electromechanical reaction with an organic material of at least one organism present on the plant based on the at least one application of the solution. Further, the at least one organism may include bacteria, insects, fungi, viruses, etc. Further, the organic material may include lipid, protein, etc. Further, the creating of the electromechanical reaction disassembles the organic material for
eliminating the at least one organism. Further, the carbanions may be capable of controlling the fungi, the bacteria, the viruses, the insects, etc. present on the at least one agricultural crop based on the eliminating.
Further, in some embodiments, the at least one application of the solution may include dispensing the solution in soil associated with the plant. Further, the carbanions are cable of increasing an electrical conductivity of the soil based on
the dispensing. Further, at least one nutrient transfers from the soil to the plant based on the increasing of the electrical conductivity. Further, the solution may moisten the soil based on the dispensing. Further, the solution may simulate an
electrical conductivity response of the soil. Further, the increasing of the electrical conductivity enables more active transfer of the at least one nutrient from the soil to the plant. Further, the at least one nutrient may include a micronutrient, a
macronutrient, etc. Further, the at least one nutrient may include Mn (manganese), Cu (copper), Zn (zinc), Fe (iron), etc.
Further, in some embodiments, the solution may include a pesticide. Further, the pesticide may be capable of eliminating the at least one of the fungi, the bacteria, the viruses, and the insects from the at least one agricultural plant.
Further, in an embodiment, the pesticide may be a metabolic pesticide. Further, the metabolic pesticide generates a metabolite based on the at least one application of the metabolic pesticide. Further, the metabolite may include a plurality of single
carbanions. Further, the plurality of single carbanions may be capable of eliminating the at least one of the fungi, the bacteria, the viruses, and the insects from the at least one agricultural plant.
Further, in some embodiments, the at least one organic material source may include biomass. Further, the carbanions may be bio-based.
Further, in some embodiments, the carbanions may be provided in a dosage for facilitating the production of the at least one agricultural crop. Further, the dosage may include 5 oz. per acre. Further, the 5 oz. may include 1765 drops.
Further, the 1765 drops may include at least 8,875 sextillion carbanions.
Further, in some embodiments, the carbanions may be provided in a dosage for facilitating soil remediation and fertilizer recovery of the soil. Further, the dosage may include 8 oz. per acre. Further, the 8 oz. may include 2840 drops.
Further, the 2840 drops may include 14,200 sextillion carbanions.
Further, in some embodiments, the carbanion may include negatively charged carbon atoms. Further, the negatively charged carbon atoms may not be active ingredients. Further, the negatively charged carbon atoms may attract positive atoms and
release the vital fluid from at least one of the fungi, the bacteria, the viruses, and the insects causing the elimination of the at least one of the fungi, the bacteria, the viruses, and the insects. Further, the negatively charged carbon atoms may
make surfaces of the pests positively charged by knocking electrons out from the surfaced of pests.
Further, in some embodiments, the carbanions may forms particles in the solution. Further, the particles may be associated with a particle size. Further, the particle size may be less than 1 nanometer in a straight solution. Further, in an
instance, the particle size may be 0.6 nm or 600 pm. Further, the carbanions may include micelles structures. Further, the micelles structure may include a spherical shape. Further, most micelles may be 0.6 nm in particle size hydrodynamic radius.
Further, in some embodiment, the carbanion of the carbanions may include a single negatively charged carbon atom. Further, the single negatively charged carbon atom bond to no other atoms except for another single negatively charged carbon
atom.
Further, the carbanion may include "Negative Octet Energy". Further, the carbanion may be an anion in which the carbon-atom bears a formal negative charge.
In further embodiments, a product may include the carbanions and the diluting agent. Further, the product may include PicoAg 25BF. Further, the PicoAg 25BF may be 100% organic matter. Further, the organic matter may include organic carbon
atoms. Further, the PicoAg 25B may be 89% New Carbon. Further, a new carbon atom may be 100% organic. Further, in an embodiment, the product may include PicoAg 25BF. Further, the PicoAg 25BF may be configured recovering of the fertilizer in the soil. Further, the PicoAg 25BF may be configured for making the fertilizer in the soil. Further, the PicoAg 25BF may be configured for applying on the soil. Further, the PicoAg 25BF may be associated a product concentration. Further, the PicoAg 25BF may be
configured for increasing a concentration of at least one element present in the soil based on the applying. Further, the concentration may be associated with parts per million (ppm). Further, the parts per million may be associated with mill moles/l.
Further, the at least one element may include at least one ion, at least one chemical element, at least one compound, etc. Further, the at least one chemical element may include Ferrum (Fe), Manganese (Mn), Zinc (Zn), etc. Further, the at least one ion
may include at least one monoatomic ion, at least one polyatomic ion, etc. Further, in an embodiment, the PicoAg 25BF may kill the viruses by eliminating strands of nucleic acid of the viruses, either DNA or RNA of the viruses, and protective protein
coat of the viruses (the capsid), or a lipid envelope of the viruses surrounding the protein of the viruses.
In further embodiments, PicoAg may include the carbanions. Further, the PicoAg may be applied to the at least one agricultural crop using the in-furrow application. Further, the at least one agricultural crop may include Grain Sorghum.
Further, the PicoAg may be applied in a dosage. Further, the dosage may include 1.25 oz. per acre. Further, in an embodiment, the Sosoap may be applied to the at least one agricultural crop in a number of applications during a specified period.
Further, a dosage of the PicoAg may be applied in the number of applications. Further, in an embodiment, the PicoAg may be applied to the at least one agricultural crop using the foliar application. Further, the PicoAg may be blended with the diluting
agent to form the solution. Further, the solution may be applied to the at least one agricultural crop. Further, the solution with chelated trace elements increases the availability of the trace elements to the at least one agricultural crop. Further,
in an embodiment, the PicoAg may be applied in the solution. Further, the solution may include the PicoAg in at least one PicoAg volume and the diluting agent in at least one diluting volume. Further, the at least one PicoAg volume may be 1.5 oz.
Further, the diluting agent may include water. Further, the at least one diluting volume may be 16 liters. Further, the solution may be applied to the at least one agricultural crop in a dosage. Further, the dosage may be applied to the agricultural
crops in the number of applications.
FIG. 2 is a flowchart of a method 200 for producing an agricultural composition to facilitate treatment of a plant, in accordance with some embodiments. Further, at 202, the method 200 may include a step of extracting at least one organic
material from at least one organic material source. Further, the at least one organic material source may include at least one plant. Further, the at least one organic material may be 100% biomass. Further, the at least one organic material may
include a carbon compound. Further, the carbon compound may be an organic carbon compound.
Further, at 204, the method 200 may include a step of blending the at least one organic material with at least one reagent for forming an agricultural composition preform. Further, the at least one reagent may include a reducing agent.
Further, at 206, the method 200 may include a step of applying at least one of a specific temperature and a specific pressure to the agricultural composition preform. Further, the applying initiates a chemical reaction in the agricultural
composition preform. Further, the chemical reaction may include at least one of a redox reaction and a reduction reaction. Further, the carbon compound may be reduced to form carbanions based on the at least one of the redox reaction and the reduction
reaction. Further, the at least one reagent reduces the carbon compound to form the carbanions based on the applying. Further, a carbon atom of a carbanion of the carbanions may include a formal charge of -1.
Further, at 208, the method 200 may include a step of dissolving the carbanions using a diluting agent for forming a solution. Further, the diluting agent may include water. Further, the dissolving of the carbanions may include diluting the
carbanions. Further, a ratio of the diluting agent to the carbanions by volume ranges from 50:1 to 550:1. Further, the dissolving facilitates at least one application of the solution to the plant. Further, the plant may include at least one
agricultural crop. Further, the at least one application may include spraying, dispensing, etc. Further, the at least one application may include an in-furrow application, a foliar application, etc. Further, the solution may be applied to the plant in
at least one vegetative state of the plant.
Further, in some embodiments, the at least one of the redox reaction and the reduction reaction adds a pair of electrons to a carbon atom of the carbon compound for producing the carbanion. Further, the carbon atom may be associated with sp3
hybridization state. Further, the carbon atom in the sp3 hybridization state may be trivalent. Further, the carbon atom in the sp3 hybridization state may include a lone pair of electrons on the carbon atom.
Further, in some embodiments, the solution may include a dispersing agent. Further, the dispersing agent may be capable of dispersing the carbanions in the diluting agent. Further, the carbanions are present in the solution in a form of
granules. Further, a size of a granule of the granules may be 340 pm (picometer).
In further embodiments, the method 200 may include a step of adding a chelating agent to the solution. Further, the chelating agent may be capable of chelating at least one nutrient associated with the plant. Further, the solution may be
capable of mobilizing the at least one nutrient from the chelating agent to the plant based on the at least one application of the solution to the plant.
Further, in some embodiments, the solution may include a surface tension reducing agent. Further, the surface tension reducing agent may be capable of reducing a surface tension of water associated with the plant. Further, the solution may be
capable of enhancing an internal translocation of at least one nutrient associated with the plant through at least one of a xylem system and a phloem system of the plant based on the reducing.
Further, in some embodiments, the solution may include a solvent agent. Further, the solvent agent may be capable of softening a surface of at least one part of the plant based on the at least one application of the solution to the plant.
Further, at least one nutrient enters into at least one circulation pathway of the plant through the surface of the at least one part of the plant based on the softening.
Further, in some embodiments, each carbanion of the carbanions may be capable of creating an electromechanical reaction with an organic material of at least one organism present on the plant based on the at least one application of the solution. Further, the creating of the electromechanical reaction disassembles the organic material for eliminating the at least one organism.
FIG. 3 is a flowchart of a method 300 for producing a solution of the carbanions and a diluting agent, in accordance with some embodiments. Further, the solution may be dispensed on the soil of 1 acre of land. Further, the solution may be
applied to the plant using at least one application of the solution. Further, at 302, the method 300, may include a step of measuring a dosage of the carbanions. Further, the dosage may include 8 ounces of the carbanions. Further, the 8 ounces may
include 2840 drops. Further, the 2840 drops may include 14,200 sextillion carbanions.
Further, at 304, the method 300 may include measuring a diluting volume of the diluting agent. Further, the diluting agent may include water. Further, the diluting volume may be 16 liters.
Further, at 306, the method 300 may include a step of mixing the dosage of the carbanions with the diluting volume of the diluting agent. Further, a ratio of the diluting agent to the carbanions by volume is 70:1
Further, at 308, the method 300 may include a step of producing the solution based on the mixing. Further, the solution may be applied to the plant using at least one application. Further, the at least one application may include spraying,
dispensing, etc. Further, the at least one application may include an in-furrow application, a foliar application, etc.
FIG. 4 is an illustration of carbanions 400 of the agricultural composition, in accordance with some embodiments. Further, the carbanions 400 may be derived from at least one organic material source. Further, the at least one organic material
source may include at least one plant. Further, the carbanions 400 may include carbon atoms extracted from the at least one plant. Further, the carbanions 400 may include a 100% organic matter. Further, the organic matter may be organic carbon atoms.
Further, at least one of a specific temperature and a specific pressure may be applied to the carbon atoms for initiating at least one of a reduction reaction and a redox reaction. Further, the at least one of the reduction reaction and the redox
reaction adds 2 electrons to the carbon atoms for creating negatively charged carbon atoms. Further, each negatively charged carbon atom of the negatively charged carbon atoms may include 8 electrons and 6 protons, and 6 neutrons. Further, the
negatively charged carbon atoms may be highly negatively charged. Further, the negatively charged carbon atoms may be the carbanions 400. Further, the carbanions 400 may include a trivalent carbon atom comprising eight (8) electrons in the valence
shell of the trivalent carbon atom. Further, the carbanions 400 may be created using physical chemistry of the carbanions 400. Further, the carbanions 400 may include micelles structures. Further, the micelles structure may include a spherical shape.
FIG. 5 is a plot of light scattering by the carbanions through a dynamic light scattering, in accordance with some embodiments. Further, the dynamic light scattering may be a technique for measuring a particle size. Further, the particle size
range from a few nanometers (nm) to a few microns. Further, the light intensity may be proportional to the size of "aggregates". Further, the dynamic light scattering may be an excellent tool for translocation. Further, 0.6 nm peaks may show greater
intensity-weight distribution. Further, large aggregates scatter the storing light for 0.6 nm peak. Further, most micelles may be 0.6 nm in particle size hydrodynamic radius.
FIG. 6 is a magnified view of a sample of a solution of the agricultural composition, in accordance with some embodiments. Further, the solution may include a 1:1 dilution. Further, the sample of the solution may be magnified up to
100,000.times.. Further, the sample of the solution may include droplets with small grains. Further, the droplets may include the carbanions.
FIG. 7 is a magnified view of a sample of the solution, in accordance with some embodiments. Further, the solution may include a 1:1 dilution. Further, the sample of the solution may be magnified up to 100,000.times.. Further, the sample of
the solution may include droplets with small grains. Further, the droplets may include the carbanions.
FIG. 8 is a magnified view of a sample of a solution of the agricultural composition, in accordance with some embodiments. Further, the solution may include a 1:100 dilution. Further, the sample of the solution may be magnified up to
100,000.times.. Further, the sample of the solution may include droplets with small grains. Further, the droplets may include the carbanions.
FIG. 9 is a magnified view of a sample of the solution, in accordance with some embodiments. Further, the solution may include a 1:100 dilution. Further, the sample of the solution may be magnified up to 100,000.times.. Further, the sample of
the solution may include droplets with small grains. Further, the droplets may include the carbanions.
FIG. 10 is a magnified view of a sample of a solution of the agricultural composition, in accordance with some embodiments. Further, the solution may include a straight solution. Further, the solution may be magnified up to 100,000.times..
Further, the sample of the solution may include droplets. Further, the droplets may include similar size particles around the edges, but inside, the grain is less than 1 nm (nanometer). Further, the droplets may include the carbanions.
FIG. 11 is a schematic of a carbanion 1100 of the carbanions, in accordance with some embodiments. Further, the carbanion 1100 is an anion in which carbon bears a formal negative charge. Further, the carbanion 1100 may include eight electrons
in the valence shell of the carbon. Further, a carbon-atom of the carbanion 1100 may include a negative charge. Further, the valence shell of a negatively charged carbon-atom may include 8-electrons. Further, the octet of the negatively charged carbon
atom may be complete. Further, the negatively charged carbon atom may include an extra pair of electrons. Further, the negatively charged carbon may be in a state of sp3 hybridization. Further, the hybrid orbitals may be directed towards the corners
of a tetrahedron. Further, three of the hybrid orbitals may be involved in the formation of single covalent bonds with other atoms while the fourth hybrid orbital may include a lone pair of electron. Further, the carbanion 1100 may include a pyramidal
structure similar to NH3 molecule. Further, the carbon-atom may include eight electrons even the carbon-atom may be a highly reactive intermediate. Further, the carbon-atom may be readily attacked by electrophilic reagents. Further, the carbanion 1100
may be a nucleophile.
Although the present disclosure has been explained in relation to its preferred embodiment, it is to be understood that many other possible modifications and variations can be made without departing from the spirit and scope of the disclosure.
Medicine composition for facilitating treating organs of a mammal
United States Patent |
11,000,541 |
Wilshe
|
May 11, 2021
|
Medicine composition for facilitating treating organs of a mammal
Abstract
Disclosed herein is a medicine composition for facilitating treating
organs of a mammal, in accordance with some embodiments. Accordingly, the
medicine composition may include carbanions and a diluting agent.
Further, a carbanion of the carbanions may include a carbon atom.
Further, the carbon atom may include a formal charge of -1. Further, the
diluting agent may be capable of combining with the carbanions for
forming at least one appliable form of the medicine composition. Further,
a ratio of the diluting agent to the carbanions by volume ranges from
512:1 to 32:1. Further, the combining facilitates applying of the at
least one appliable form of the medicine composition to at least one
organ of the mammal.
Inventors: |
Wilshe; Donald Richard (Parrish, FL) |
Applicant: | Name | City | State | Country | Type | Wilshe; Donald Richard | Parrish | FL | US |
|
|
Family ID:
|
75845858
|
Appl. No.:
|
17/173,995 |
Filed:
|
February 11, 2021 |
Related U.S. Patent Documents
| | | | | |
| Application Number | Filing Date | Patent Number | Issue Date | |
---|
| 63022970 | May 11, 2020 | | | |
| 63029263 | May 22, 2020 | | | |
| 63046013 | Jun 30, 2020 | | | |
| 63045993 | Jun 30, 2020 | | | |
|
Current U.S. Class: | 1/1 |
Current CPC Class: |
A61P 31/04 (20180101); A61K 9/0014 (20130101); A61K 47/46 (20130101); A61K 9/0078 (20130101); A61K 9/107 (20130101); A61K 47/44 (20130101); A61K 9/06 (20130101); A61K 9/08 (20130101); A61K 33/00 (20130101) |
Current International Class: |
A61K 33/00 (20060101); A61K 9/06 (20060101); A61K 9/107 (20060101); A61K 9/00 (20060101); A61K 47/44 (20170101); A61K 47/46 (20060101); A61P 31/04 (20060101) |
References Cited [Referenced By]
U.S. Patent Documents
Primary Examiner: Holloman; Nannette
Claims
What is claimed is:
1. A medicine composition for facilitating treating organs of a mammal, the medicine composition comprising: carbanions, wherein a carbanion of the carbanions comprises a
carbon atom, wherein the carbon atom comprises a formal charge of -1; and a diluting agent, wherein the diluting agent is capable of combining with the carbanions for forming at least one appliable form of the medicine composition, wherein a ratio of
the diluting agent to the carbanions by volume ranges from 512:1 to 32:1, wherein the combining facilitates applying of the at least one appliable form of the medicine composition to at least one organ of the mammal.
2. The medicine composition of claim 1, wherein the ratio of the diluting agent to the carbanions by the volume is 284:1.
3. The medicine composition of claim 1, wherein the ratio of the diluting agent to the carbanions by the volume is 189:1.
4. The medicine composition of claim 1, wherein the ratio of the diluting agent to the carbanions by the volume is 57:1.
5. The medicine composition of claim 1 further comprising an elemental composition in a ratio to the carbanions by volume, wherein the ratio of the elemental composition to the carbanions by the volume is 1:9.
6. The medicine composition of claim 5, wherein the elemental composition comprises oxygen, hydrogen, nitrogen, phosphorus, potassium, calcium, magnesium, sulfur, iron, silicon, aluminum, chlorine, and manganese.
7. The medicine composition of claim 1, wherein each carbanion of the carbanions is capable of creating an electromechanical reaction with an organic material of at least one organism present on the at least one organ of the mammal based on the
applying of the at least one appliable form of the medicine composition, wherein the creating of the electromechanical reaction disassembles the organic material of the at least one organism for eliminating the at least one organism, wherein the
eliminating of the at least one organism facilitates the treating of the at least one organ of the mammal.
8. The medicine composition of claim 1, wherein the carbanions are derived from at least one organic material, wherein the at least one organic material is associated with at least one part of at least one plant, wherein the at least one plant
comprises a corn plant, wherein the at least one part of the corn plant comprises a leaf, a stem, a grain, a root, and a cob.
9. The medicine composition of claim 1, wherein the diluting agent comprises at least one cream, wherein the at least one cream comprises a shea butter.
10. The medicine composition of claim 1, wherein the diluting agent comprises at least one moisturizing element.
11. A method for facilitating treating organs of a mammal using a medicine composition, the method comprising: transforming, using at least one application device, the medicine composition into at least one appliable form, wherein the medicine
composition comprises carbanions and a diluting agent, wherein a carbanion of the carbanions comprises a carbon atom, wherein the carbon atom comprises a formal charge of -1, wherein the diluting agent is capable of combining with the carbanions for
forming the at least one appliable form of the medicine composition, wherein a ratio of the diluting agent to the carbanions by volume ranges from 512:1 to 32:1; and applying, using the at least one application device, at least one dosage of the at
least one appliable form of the medicine composition on at least one organ of the mammal based on the transforming, wherein the applying of the at least one dosage of the at least one appliable form of the medicine composition facilitates the treating of
the at least one organ of the mammal.
12. The method of claim 11, wherein the at least one application device comprises a nebulizer, wherein the at least one organ comprises at least one lung, wherein the at least one appliable form of the medicine composition comprises an aerosol,
wherein the transforming comprises aerosolizing the medicine composition into the aerosol, wherein the applying comprises delivering the aerosol to the at least one lung of the mammal.
13. The method of claim 11, wherein the at least one application device comprises an emulsifier, wherein the at least one organ comprises skin, wherein the at least one appliable form of the medicine composition comprises an emulsion, wherein
the transforming comprises emulsifying the medicine composition into the emulsion, wherein the applying comprises covering the skin of the mammal with the emulsion.
14. The method of claim 11 further comprising generating, using the at least one application device, the at least one dosage of the at least one appliable form of the medicine composition, wherein the applying of the at least one dosage of the
at least one appliable form of the medicine composition is further based on the generating of the at least one dosage.
15. The method of claim 11, wherein the at least one dosage of the at least one appliable form of the medicine composition comprises one ounce of water and at least three drops of the carbanions, wherein the diluting agent comprises the water.
16. The method of claim 11, wherein the treating of the at least one organ comprises eliminating at least one organism from the at least one organ causing at least one disease in the at least one organ of the mammal based on the applying,
wherein the eliminating comprises disassembling an organic material of the at least one organism based on an interaction of the carbanions with the organic material based on the applying.
17. The method of claim 11, wherein the treating of the at least one organ comprises regenerating at least one tissue of the at least one organ of the mammal based on the applying.
18. The method of claim 11, wherein the at least one dosage of the at least one appliable form of the medicine composition is associated with a dosing frequency, wherein the dosing frequency comprises three times a day for at least one three
days, wherein the applying of the at least one dosage of the at least one appliable form of the medicine composition with the dosing frequency facilitates the treating of the at least one organ.
19. The method of claim 11, wherein the applying of the at least one appliable form of the medicine composition is associated with an applying duration, wherein the treating of the at least one organ is based on the applying of the at least one
appliable form of the medicine composition for the applying duration.
20. The method of claim 11, wherein the at least one appliable form of the medicine composition comprises a solution, wherein the solution is appliable to the at least one organ using at least one application method, wherein the applying of the
solution of the medicine composition to the at least one organ facilitates the treating of the at least one organ.
Description
FIELD OF THE INVENTION
Generally, the present disclosure relates to the field of Drug, bio-affecting, and body treating compositions. More specifically, the present disclosure relates to a medicine composition for facilitating treating organs of a mammal.
BACKGROUND OF THE INVENTION
When it comes to treatment for diseases caused by organisms such as viruses bacteria, fungi, insects, it may be a financial issue for people who are in need of treatment. Further, the organism such as the viruses, the bacterial, fungi, insects,
etc. may infect organs of mammal such as humans causing the diseases. Further, treatments for infectious viruses causing the diseases may vary in price. For the very common and well-known virus, the materials needed to produce a treatment for the said
virus will most likely be relatively cheap. On the other hand, for the more rare and undiscovered virus, the materials needed to produce a treatment for the said virus will definitely be expensive as there are lesser known cases of the rare virus, and
maybe more difficult to find a treatment. Another issue with infectious viruses is that not all of the viruses have been studied as there is an unknown number of undiscovered viruses. One prime example of an unknown virus was COVID-19. In December
2019, COVID-19 was newly discovered as an outbreak occurred from Wuhan, China. COVID-19 lead to an international pandemic. Due to the unknown virus COVID-19, the treatment for COVID-19 has yet been discovered even a few months after the discovery of
the virus itself. The complexity of finding and producing a treatment for COVID-19 is extremely difficult due to the anomaly of the newly discovered virus.
Existing compositions for facilitating treating organs of a mammal are deficient with regard to several aspects. For instance, existing compositions do not perform treatment of various organs of a mammal. Furthermore, existing compositions do
not eliminate viruses, bacteria, fungi, and insects present on various organs for treating the various organs. Moreover, existing compositions do not totally derive from organic matter.
Therefore, there is a need for an improved medicine composition for facilitating treating organs of a mammal that may overcome one or more of the above-mentioned problems and/or limitations.
SUMMARY OF THE INVENTION
This summary is provided to introduce a selection of concepts in a simplified form, that are further described below in the Detailed Description. This summary is not intended to identify key features or essential features of the claimed subject
matter. Nor is this summary intended to be used to limit the claimed subject matter's scope.
Disclosed herein is a medicine composition for facilitating treating organs of a mammal, in accordance with some embodiments. Accordingly, the medicine composition may include carbanions and a diluting agent. Further, a carbanion of the
carbanions may include a carbon atom. Further, the carbon atom may include a formal charge of -1. Further, the diluting agent may be capable of combining with the carbanions for forming at least one appliable form of the medicine composition. Further,
a ratio of the diluting agent to the carbanions by volume ranges from 512:1 to 32:1. Further, the combining facilitates applying of the at least one appliable form of the medicine composition to at least one organ of the mammal.
Further disclosed herein is a method for facilitating treating organs of a mammal using a medicine composition, in accordance with some embodiments. Accordingly, the method may include a step of transforming, using at least one application
device, the medicine composition into at least one appliable form. Further, the medicine composition may include carbanions and a diluting agent. Further, a carbanion of the carbanions may include a carbon atom. Further, the carbon atom may include a
formal charge of -1. Further, the diluting agent may be capable of combining with the carbanions for forming the at least one appliable form of the medicine composition. Further, a ratio of the diluting agent to the carbanions by volume ranges from
512:1 to 32:1. Further, the method may include a step of applying, using the at least one application device, at least one dosage of the at least one appliable form of the medicine composition on at least one organ of the mammal based on the
transforming. Further, the applying of the at least one dosage of the at least one appliable form of the medicine composition facilitates the treating of the at least one organ of the mammal.
Both the foregoing summary and the following detailed description provide examples and are explanatory only. Accordingly, the foregoing summary and the following detailed description should not be considered to be restrictive. Further,
features or variations may be provided in addition to those set forth herein. For example, embodiments may be directed to various feature combinations and sub-combinations described in the detailed description.
BRIEF DESCRIPTION OF THE DRAWINGS
The accompanying drawings, which are incorporated in and constitute a part of this disclosure, illustrate various embodiments of the present disclosure. The drawings contain representations of various trademarks and copyrights owned by the
Applicants. In addition, the drawings may contain other marks owned by third parties and are being used for illustrative purposes only. All rights to various trademarks and copyrights represented herein, except those belonging to their respective
owners, are vested in and the property of the applicants. The applicants retain and reserve all rights in their trademarks and copyrights included herein, and grant permission to reproduce the material only in connection with reproduction of the granted
patent and for no other purpose.
Furthermore, the drawings may contain text or captions that may explain certain embodiments of the present disclosure. This text is included for illustrative, non-limiting, explanatory purposes of certain embodiments detailed in the present
disclosure.
FIG. 1 is a table listing ingredients of a medicine composition for facilitating treating organs of a mammal, in accordance with some embodiments.
FIG. 2 is a flowchart of a method for facilitating treating organs of a mammal using a medicine composition, in accordance with some embodiments.
FIG. 3 is an illustration of carbanions of the medicine composition, in accordance with some embodiments.
FIG. 4 is a front view of a container containing the medicine composition, in accordance with some embodiments.
FIG. 5 is a plot of light scattering by the carbanions through a dynamic light scattering, in accordance with some embodiments.
FIG. 6 is a magnified view of a sample of a solution of the medicine composition, in accordance with some embodiments.
FIG. 7 is a magnified view of a sample of the solution, in accordance with some embodiments.
FIG. 8 is a magnified view of a sample of a solution of the medicine composition, in accordance with some embodiments.
FIG. 9 is a magnified view of a sample of the solution, in accordance with some embodiments.
FIG. 10 is a magnified view of a sample of a solution of the medicine composition, in accordance with some embodiments.
FIG. 11 is a schematic of a carbanion of the carbanions, in accordance with some embodiments.
FIG. 12 is an illustration of gram-positive bacteria.
FIG. 13 is an illustration of gram-negative bacteria.
FIG. 14 is an illustration of an effect of NG 1 on Alternaria alternata, in accordance with some embodiments.
FIG. 15 is an illustration of an effect of NG 2 on Sclerotium rolfsii, in accordance with some embodiments.
FIG. 16 is an illustration of an effect of NG 1 on Macrophomina phaseolina, in accordance with some embodiments.
FIG. 17 is a table of an initial screen of pathogens vs. dilution of Formula S-101, in accordance with some embodiments.
FIG. 18 is a table of a second screen of pathogens vs. dilution of Formula S-101, in accordance with some embodiments.
FIG. 19 is a table of the second screen of pathogens vs. dilution of Formula S-101, in accordance with some embodiments.
FIG. 20 is a table of a subset of the second screen of pathogens vs. dilutions of Formula S-101, in accordance with some embodiments.
FIG. 21 is a table of therapeutic options for fungal lung infections.
FIG. 22 is a table of antifungal treatment options.
FIG. 23 is a flow diagram of a method of facilitating producing the medicine composition for treating diseases using the medicine composition, in accordance with some embodiments.
FIG. 24 is a flow diagram of the method of facilitating producing the medicine composition for treating the diseases using the medicine composition, in accordance with some embodiments.
FIG. 25 is a flow diagram of the mining stage of the method, in accordance with some embodiments.
FIG. 26 is a flow diagram of the mixture stage of the method, in accordance with some embodiments.
FIG. 27 is a flow diagram of the production stage of the method, in accordance with some embodiments.
FIG. 28 is a flow diagram of the treatment stage of the method, in accordance with some embodiments.
FIG. 29 is a table of compositional elements of the medicine composition, in accordance with some embodiments.
FIG. 30 is a chart of the lab results of the medicine composition, in accordance with some embodiments.
FIG. 31 is a table of compositional elements of the medicine composition, in accordance with some embodiments.
DETAIL DESCRIPTIONS OF THE INVENTION
As a preliminary matter, it will readily be understood by one having ordinary skill in the relevant art that the present disclosure has broad utility and application. As should be understood, any embodiment may incorporate only one or a
plurality of the above-disclosed aspects of the disclosure and may further incorporate only one or a plurality of the above-disclosed features. Furthermore, any embodiment discussed and identified as being "preferred" is considered to be part of a best
mode contemplated for carrying out the embodiments of the present disclosure. Other embodiments also may be discussed for additional illustrative purposes in providing a full and enabling disclosure. Moreover, many embodiments, such as adaptations,
variations, modifications, and equivalent arrangements, will be implicitly disclosed by the embodiments described herein and fall within the scope of the present disclosure.
Accordingly, while embodiments are described herein in detail in relation to one or more embodiments, it is to be understood that this disclosure is illustrative and exemplary of the present disclosure, and are made merely for the purposes of
providing a full and enabling disclosure. The detailed disclosure herein of one or more embodiments is not intended, nor is to be construed, to limit the scope of patent protection afforded in any claim of a patent issuing here from, which scope is to
be defined by the claims and the equivalents thereof. It is not intended that the scope of patent protection be defined by reading into any claim limitation found herein and/or issuing here from that does not explicitly appear in the claim itself.
Thus, for example, any sequence(s) and/or temporal order of steps of various processes or methods that are described herein are illustrative and not restrictive. Accordingly, it should be understood that, although steps of various processes or
methods may be shown and described as being in a sequence or temporal order, the steps of any such processes or methods are not limited to being carried out in any particular sequence or order, absent an indication otherwise. Indeed, the steps in such
processes or methods generally may be carried out in various different sequences and orders while still falling within the scope of the present disclosure. Accordingly, it is intended that the scope of patent protection is to be defined by the issued
claim(s) rather than the description set forth herein.
Additionally, it is important to note that each term used herein refers to that which an ordinary artisan would understand such term to mean based on the contextual use of such term herein. To the extent that the meaning of a term used
herein--as understood by the ordinary artisan based on the contextual use of such term--differs in any way from any particular dictionary definition of such term, it is intended that the meaning of the term as understood by the ordinary artisan should
prevail.
Furthermore, it is important to note that, as used herein, "a" and "an" each generally denotes "at least one," but does not exclude a plurality unless the contextual use dictates otherwise. When used herein to join a list of items, "or" denotes
"at least one of the items," but does not exclude a plurality of items of the list. Finally, when used herein to join a list of items, "and" denotes "all of the items of the list."
The following detailed description refers to the accompanying drawings. Wherever possible, the same reference numbers are used in the drawings and the following description to refer to the same or similar elements. While many embodiments of
the disclosure may be described, modifications, adaptations, and other implementations are possible. For example, substitutions, additions, or modifications may be made to the elements illustrated in the drawings, and the methods described herein may be
modified by substituting, reordering, or adding stages to the disclosed methods. Accordingly, the following detailed description does not limit the disclosure. Instead, the proper scope of the disclosure is defined by the claims found herein and/or
issuing here from. The present disclosure contains headers. It should be understood that these headers are used as references and are not to be construed as limiting upon the subjected matter disclosed under the header.
The present disclosure includes many aspects and features. Moreover, while many aspects and features relate to, and are described in the context of a medicine composition for facilitating treating organs of a mammal, embodiments of the present
disclosure are not limited to use only in this context.
Overview:
The present disclosure describes a medicine composition for facilitating treating organs of a mammal. Further, the medicine composition may include carbanions. Further, the carbanions facilitate the treating of the organs of the mammal.
Further, the present disclosure describes a method for treating the organs using the medicine composition.
Further, the present disclosure may provide a treatment of the contagious and infectious lung bacterial and fungi diseases. Furthermore, the present disclosure may provide a cheap and cost-efficient treatment for the contagious and/or
infectious lung bacterial, and fungi diseases. The present disclosure also provides a treatment to cure multiple known lung bacterial and fungi diseases and potentially undiscovered lung bacterial and fungi diseases. The present disclosure may include
a mining stage, a mixture stage, a production stage, and a treatment stage.
Further, the present describes carbanions for facilitating COVID-19 Treatment, Control of Viruses, Fungi, Bacteria, and Insect, and Adjuvant & Nebulized Drug Delivery to Lungs and Skin of the Mammal.
Further, the carbanions may include individual atoms. Further, the carbanions may include negatively charged carbon atoms. Further, the negatively charged carbon atom may include a formal charge of -1. Further, the negatively charged carbon
atoms may be created by making use of the physical chemistry of carbon atoms. Further, the physical chemistry may be the study of macroscopic, atomic, subatomic, and particulate phenomena in chemical systems in terms of the principles, practices, and
concepts of physics such as motion, energy, force, time, thermodynamics, quantum chemistry, statistical mechanics, analytical dynamics and chemical equilibrium. Further, the carbanions may be created by making the use of the physical chemistry of the
carbanions. Further, the physical chemistry may be the study of macroscopic, atomic, subatomic, and particulate phenomena in chemical systems in terms of the principles, practices, and concepts of physics such as motion, energy, force, time,
thermodynamics, quantum chemistry, statistical mechanics, analytical dynamics and chemical equilibrium. Further, the physical chemistry is the study of how matter behaves on a molecular and atomic level and how chemical reactions occur. Based on the
analyses, physical chemists may develop new theories, such as how complex structures are formed. Physical chemists often work closely with materials scientists to research and develop potential uses for new materials. Further, the physical chemistry
may be used in observing the assembly of molecules and determining, measuring, and quantifying the assembly of the molecules. Further, the physical chemistry may allow for assembling of molecules in crystals and solutions and observing and measuring of
the arrangements of atoms and molecules and aggregates of the atoms and the molecules in the solutions as well as in crystals and various properties the aggregates of surfactants impart to a product. Further, diffraction, infrared, and microscopy
methods are used for observing the assembly of the molecules and further determining, measuring, and quantifying the assembly of the molecules. Further, the physical chemistry may be used for developing better ways to measure and quantify aspects of the
ingredients for developing better products. Further, physical chemistry provides an understanding of the physical properties of atoms and molecules, the way chemical reactions work, and what these properties reveal. Further, the physical chemistry
involves analyzing materials, developing methods to test and characterize the properties of materials, developing theories about these properties, and discovering the potential use of the materials. Using sophisticated instrumentation and equipment has
always been an important aspect of physical chemistry. Most physical chemistry labs are full of analytical instruments, which may include lasers, mass spectrometers, nuclear magnetic resonance, and electron microscopes. Further, the physical chemistry
may provide an understanding of chemical properties and describes the behavior of chemicals using theories of physics and mathematical computations. Further, the properties and reactions of the chemicals may be predicted using the physical chemistry.
Physical chemistry describes fundamental physical characteristics of material be it solid, liquid, or gas. Further, the physical chemistry may be used for the development of materials, including plastics, ceramics, catalysis, electronics, fuel,
batteries, surfactants, and colloids, and personal care products.
Further, the carbanions may include carbon atoms. Further, the carbon atoms may be associated with CO2 (carbon dioxide) gas. Further, an average person breathes out around 500 liters of the greenhouse gas CO2, which amounts to around 1 kg or
2.3 pounds of mass. Further, the world's population is around 6.8 billion, collectively breathing out around 2500 million tons of the CO2, which is around 7 percent of the annual CO2 tonnage churned out by the burning of fossil fuel around the world.
Further, the CO2 breath out by the average person may be a part of a natural cycle, by which the body of the average person may convert carbohydrates from CO2-absorbing plants into energy, plus water and CO2. Further, the average person may breathe the
carbon atoms of the CO2 and consume the carbon atoms of plants.
Further, the carbanions may be created using Femtotechnology. Further, the Femtotechnology is one of the most promising realms of science, bringing new products to society in many industries. Further, the Femtotechnology is only about particle
having size 1000 times smaller than a nanometer. The product is made mostly of Carbon and Nitrogen and trace elements. There are 25,400,000 nanometers in one inch. There are 1000 Picometers in a nanometer; Therefore an inch has 25,400,000,000 Pico
meters, and a human hair is 80,000,000 to 100,000,000 Picometers thick. Further, Femtotechnology may be described as involving the alteration of the structure and the chemical properties of individual atoms through the manipulation of energy states of
electrons within the individual atoms to produce states with unusual properties, producing some form of exotic atoms. Further, the Femtotechnology may allow the usage of atoms singularly. Further, the Femtotechnology may be used for the fabrication of
structures where atoms may be positioned with sub-nanometer accuracy. This may be important where interaction with a single atom or molecule may be desired. Further, the Femtotechnology may be used for altering electron distributions around atoms to
promote surface energy to achieve inhibited infection without potential nanomaterial toxicity concerns. Further, the Femtotechnology may be used to describe the control of electron distribution around the atoms to provide desirable properties. Further,
the control of the electron distribution may greatly change surface energy and, thus, the way that proteins adsorb onto a material. Further, the excitement or rearrangement of electrons around the atoms may influence many cellular functions including
cell movement, intracellular transport to organelles, adhesion, growth, and ECM formation. Further, the Femtotechnology may control cellular microtubules (MTs). MTs are cylindrical cellular formations 25 nm in diameter, and they are made out of
tubulins. Dynamic instability due to MT plus end-binding proteins also called "plus end-tracking proteins", are able to "surf" the dynamic ends of the MTs. Further, when tips are expressed as green fluorescent proteins, the fluorescence is the
brightest at the MT and decreases in intensity toward the minus end of the MT, forming a comet tail. Further, external stimulation is used to excite the MT and end-binding proteins to promote the movement of cells using the Femtotechnology. This may be
a less toxic manner through which to alter surface energy to increase tissue growth since electron distributions may be changed for numerous macro-, micro-, or nanomaterials. Further, the Femtotechnology may be used to reduce the toxicity in any macro-,
micro-, or nanomaterials by exciting electrons. The change in electron distribution, along with the associated charge redistribution, may alter surface energetics to change the adsorption of certain proteins (as well as cellular functions).
Further, the carbanions may be created using Femto-technology. Further, the Femto-technology may be used for creating 8-octet, 9-nonet, 10-dectet, 11-undectet, and 12-duodectet by addition of electron on a carbon atom. Further, the
Femto-technology may be used for matter manipulation for modifying the carbon atom.
Further, the carbanions may be individual atoms or atoms in covalent bonds. Further, the individual atoms alone or the atoms in the covalent bonds may create powerful electromechanical reactions to disassemble organic material, one atom per
atom at a time. Further, the individual atoms alone or the atoms in the covalent bond may work on the fungi, the bacteria, or the viruses to eliminate the fungi, the bacteria, or the viruses. Further, the individual atoms alone or the atoms in the
covalent bond may eliminate Shingles, Basil Cell Cancer, Squamous Cell Cancer, Poison Ivy, Oak, Sumac, Diabetic Ulcers, Wounds, Plaque Psoriasis, Genetic Blistering, Head lice, and Whopping Cough of humans. Further, the individual atoms alone or the
atoms in the covalent bond may regenerate or grow the skins on the humans.
Further, a FemtoMed may include the carbanions. Further, the FemtoMed in a 1/512 solution may be used for treating and curing abrasions on skins.
Further, the carbanions may include FemtoMed Virus's, FemtoMed Acne Cleans, FemtoMed Actinic Keratosis, FemtoMed Alopecia Areata, FemtoMed Athlete's Foot, FemtoMed Atopic Dermatitis, FemtoMed Atopic Eczema, FemtoMed
Skin Bacteria's, FemtoMed Barrier function, firmness and elasticity, FemtoMed Beauty Habits, Skin Care, and Makeup, FemtoMed Bed Bugs, FemtoMed Biofilms Cleanse, FemtoMed Biofilms Flush Cleanse, FemtoMed Birthmarks and Other Skin
Pigmentation Problems, FemtoMed Black Seed-like "specks" or "Dots" from Lesions Cleanse, FemtoMed Black Tar-like substance from skin pores Cleanse, FemtoMed Blastomycosis, FemtoMed Boils, FemtoMed Bruises, FemtoMed Bug Bites and
Stings, FemtoMed Burns, FemtoMed Cancer, FemtoMed Canker Sores Health, FemtoMed Cellulitis, FemtoMed Chiggers (Bites), FemtoMed Collembola, FemtoMed Conditions, FemtoMed Contact Dermatitis, FemtoMed Corns, FemtoMed
Crust/Scab/Callus like Formations Cleanse, FemtoMed Cuts, Scrapes and Puncture Wounds, FemtoMed Cysts, FemtoMed Dark or black specks in your sheets Cleanse, FemtoMed Dark or black specks on your body Cleanse, FemtoMed Dercum's
Syndrome, FemtoMed Diabetics' Dry Skin Relief Rehydrating Lotion, FemtoMed Diaper Rash, FemtoMed Discolored Cleanse Cleanse, FemtoMed Divots in my skin are now flush Cleanse, FemtoMed Dry Skin, FemtoMed Eczema Relief Cream,
FemtoMed Erythema Nodosum, FemtoMed Extremely Dry, Rough, Callus, FemtoMed Fibers Black Cleanse, FemtoMed Fibers Blue Cleanse, FemtoMed Fibers Red Cleanse, FemtoMed Filaments Cleanse, FemtoMed Fire Ant Bites Infection
Prevention, FemtoMed Folliculitis, FemtoMed Freckles, FemtoMed Frostbite, FemtoMed Fungal Nails, FemtoMed Fungals and Molds Cleanse, FemtoMed Fungi's, FemtoMed Granulating Tissue hard and crystal like Cleanse, FemtoMed
Granules Above/Below Skin Cleanse, FemtoMed Hair Loss, FemtoMed Hand Cream moisturizes, FemtoMed Healing Cleanse, FemtoMed Heat Rash, FemtoMed Hematoma, FemtoMed Herpes Simplex Infections (Non-Genital), FemtoMed Hives, FemtoMed
Skin Hyperhidrosis, FemtoMed Genetic Blistering Disease, FemtoMed Inflammation yes or no Cleanse, FemtoMed Ingrown Hair, FemtoMed Ingrown Toenail, FemtoMed Intertrigo, FemtoMed Keratin 2006 For Nails, Skin and Hair, FemtoMed
Itch, FemtoMed Jock Itch, FemtoMed Keloid, FemtoMed Keratosis Pilaris, FemtoMed Lesions Cleanse, FemtoMed Lesions--Itchy, Sore, Painful, Slow Healing Cleanse, FemtoMed Lesions with Fuzzballs Cleanse, FemtoMed Lichen Planus,
FemtoMed Lichen Sclerosus, FemtoMed Loss Its Elasticity And Sags, FemtoMed Melasma, FemtoMed Moisturizing Cream For Diabetis Skin, FemtoMed Moles, FemtoMed Molluscum Contagiosum, FemtoMed New Wiry or Thick Hair Over Lesions
Before Cleanse, FemtoMed Oozing Cleansev, FemtoMed Open Sores, Wounds or Cuts Cleanse, FemtoMed Parasites Cleanse, FemtoMed Pigment Changes Cleanse, FemtoMed Pilonidal Cyst, FemtoMed Pimples long lasting Cleanse, FemtoMed
Pityriasis Rosea, FemtoMed Poison Ivy, FemtoMed Poison Oak, FemtoMed Postherpetic Neuralgia, FemtoMed Psoriasis, FemtoMed Psoriatic Arthritis, FemtoMed Rash, FemtoMed Rashes Cleanse, FemtoMed Red Cleanse, FemtoMed
Rhinoplasty, FemtoMed Ringworm, FemtoMed Rosacea, FemtoMed Rothmund-Thomson Syndrome, FemtoMed Scabbing Cleanse, FemtoMed Scabies, FemtoMed Scars, FemtoMed Seborrhea, FemtoMed Seborrheic Dermatitis, FemtoMed Seed Like
specks Cleanse, FemtoMed Sensation Biting Cleanse, FemtoMed Sensation Burning Cleanse, FemtoMed Sensation Crawling Cleanse, FemtoMed Sensation Creeping Cleanse, FemtoMed Sensation Itching Cleanse, FemtoMed Sensation Pain Cleanse,
FemtoMed Sensation Pinching Cleanse, FemtoMed Sensation Pricking Cleanse, FemtoMed Sensation Stinging Cleanse, FemtoMed Sensation Worms or wire like structures Cleanse, FemtoMed Sensitivity Cleanse, FemtoMed Shards hard and
crystal like glass Cleanse, FemtoMed Shingles (Herpes Zoster), FemtoMed Shingles and Pregnancy, FemtoMed Spider Bites (Black Widow and Brown Recluse), FemtoMed Spreading Cleanse, FemtoMed Stretch Marks, FemtoMed Strongyloides,
FemtoMed Summer Skin Hazards, FemtoMed Sun Protection and Sunscreens, FemtoMed Sun Safety, FemtoMed Sunburn and Sun Poisoning, FemtoMed Sun-Sensitive Drugs (Photosensitivity to Drugs), FemtoMed Texture--Leathery, callus-like
developed Cleanse, FemtoMed Tinea Versicolor, FemtoMed Tissue granulating and filling Cleanse, FemtoMed Venous Stasis Ulcer, Varicose Ulcers, or Ulcus Cruris, FemtoMed Vitiligo, FemtoMed Warts (Common Warts), FemtoMed
Weber-Christian Disease, FemtoMed Wrinkles, etc.
Further, the present disclosure describes femto-products comprising the carbanions. Further, the femto-products may include a FemtoMed, a PicoCare, FemtoMed, etc. Further, the femto-products comprising the carbanions may have the following
characteristics:
1). No harm to air (no GWC, ODC, VOHAP, or VOC) soil, or water.
2). cannot be made of organic chemistry, graphene, or nanotechnology, just single atom Picotechnology or physical chemistry
3). The goals are primary distribution as an OTC product.
4). It must be made of atomic elements and not molecules.
5). Must be able to kill all pests, be it bacteria, fungi, viruses, and insects.
6). Must be able to deep clean and grow skin and heal wounds just days not weeks
7). Must be able to penetrate the shields of all pests.
8). Must be approved at the State and or Federal FDA or better be exempt.
9). Must be safe for humans, bees, birds, and animals--zero side effects.
10). Must be made of 100% new organic carbon.
11). No Chemicals
12). No Biologicals
13). No Nanotechnology
14). No Graphene
15). No Molecules
16). Eliminate Sickness
Further, the femto-products may be formed using the physical chemistry. Further, the femto-products may 89% Biobased Content.
Further, the femto-products may be used for the elimination of vital elements in bacteria, insects, fungi, and viruses.
Further, the femto-products is configured for eliminating the cell membrane of the bacteria and puncturing the cell membrane. Further, the eliminating and the puncturing of the cell membrane may drain proteins and lipids from the bacteria.
Further, the femto-products is configured for eliminating the cellulose and chitin of the fungus.
Further, the femto-products is configured for eliminating strands of a nucleic acid of the virus, either DNA or RNA of the virus, and protective protein coat of the virus (the capsid), or a lipid envelope of the virus, surrounding the protein of
the virus.
Further, the femto-products is configured for dissolving cellular membranes of the insects, eliminating cells desiccation of the insects, eliminating or penetrating cellular metabolism of the insects, dissolving cuticles of the insects,
eliminating lubrication joints of the insects leading to paralysis, stripping the protective shields of the insects, eliminating exoskeleton structure of the insects, and dissolving chitin and protein substances of the insects.
Further, the femto-products immediately impacts the exoskeleton structure of the pest upon contact by disrupting the molecular structure of the chitin and other protein substances that protect the insect. This mechanism of action triggers the
rapid and irreversible deterioration of the insect's spiracles and tracheal system, resulting in suffocation. Further, the femto-products kills insects with the elimination of chitin. Further, the chitin is a polysaccharide and a carbohydrate that has a
chain of sugar molecules. Further, chitin has a structure like cellulose. Additionally, the chitin may be present in the exoskeletons of the insects.
Further, the femto-products benefit from the revolutionary method of insect control with an absence of undesirable side effects on human health and no harm to the ecosystem. Additionally, unlike standard insecticides in use today, no built-in
resistance may be developed by the targeted insects.
Further, the femto-products may be mechanical in primary sequential steps. Further, a first step is a direct interaction between the surface and the outer membrane of the pests, causing the membrane to rupture and leak fluids, proteins, and
nutrients.
Further, the femto-products may attack pests at the atom level. Further, at the atom level, the shield of the pests starts to disassemble. Further, the femto-products kills the pests by eliminating the shield.
Lastly, in a few more ways, the femto-products' electromechanical effect may affect the pests: There may be a second step related to the holes in the outer membrane, through which the pests lose vital nutrients, protein, water, and components,
causing a general weakening of the pests. Electromechanical effect of the femto-products may affect pests, the femto-products penetrates and dissolves lipid of cellular membranes of the pests. This causes cell desiccation to leak water, proteins, and
nutrients and collapse. By interfering with cellular metabolism during metamorphosis. By dissolving cuticles, the lubrication in the insect and joints of the insects, leading to paralysis. By stripping the pests' protective shields (wax, biofilm,
etc.), rendering the pests defenseless against subsequent treatment. The extracts impact the exoskeleton structure of the pests upon contact by disrupting the molecular structure of the chitin and other protein substances that protect the insect. The
extracts may have the ability to penetrate complex hydrocarbon chains and disintegrate the insects. The change in the environment for growth with PH from acidophils and neutrophils to alkaliphiles.
Further, the femto-products may be configured for punching holes in a cell of the pests. Further, the punching of the holes in the cell breaches a main defense of the cell. Further, an unopposed stream of the femto-products enters the cell.
This puts several vital processes inside the cell in danger. Further, the femto-products overwhelm the inside of the cell and obstruct cell metabolism (i.e., the biochemical reactions needed for life). Further, the femto-products bind to enzymes of the
cell halting the activity of the cell. Further, the pests no longer "breathe", "eat", "digest", "reproduce" or "exist".
Further, an outer membrane of the cell, including that of a single cell organism like pests, is characterized by a stable electrical micro-current. This is often called "transmembrane potential", and is literally, a voltage difference between
the inside and the outside of a cell. It is strongly suspected that when a pest comes in contact with the femto-products, short-circuiting of the current in the cell membrane may occur. Further, the current weakens the outer membrane and creates holes
for leaking water, proteins, and nutrients from the cell.
Further, the femto-products effects fast and affect such a wide range of pests. The experiences observed explain the speed with which pests and other pests perish on femto-products surfaces by the multi-targeted effects. Further, membrane
perforation may inhibit any given enzyme that "stands in its way," and stops the cell from transporting or digesting nutrients, repairing its damaged membrane, and breathing or multiplying. This makes the pest harmless to humans, birds, and animals.
This has no side effects or harm on human, birds, and animal health. These solutions do not harm mammal cells nor do the solutions attack the neurological systems of humans, birds, and animals. Further, the femto-products may lyse cells to extract
protein or organelles, or to permeabilize the membranes of living cells.
The femto-products dissolves lipids from cell membranes making the cell membranes permeable to antibodies. Because the organic solvents also coagulate proteins, the femto-products may be used to fix and permeabilize cells at the same time.
Saponin interacts with membrane cholesterol, selectively removing it and leaving holes in the membrane. Permeabilization is the process of making something, such as a membrane or cell wall, permeable. Lyse is a verb referring to the process of lysis,
the death of a cell. Lysis refers to the breaking down of the membrane of a cell, often by viral, enzymic, or osmotic mechanisms that compromise cell integrity. A fluid containing the contents of lysed cells is called a lysate. In molecular biology,
biochemistry, and cell biology laboratories, cell cultures may be subjected to lysis in the process of purifying the components, as protein purification, DNA extraction, RNA extraction, or purifying organelles.
Trophobiosis Cycle: Pesticides weaken plants. Weakened plants open the door to pests and disease. Further, the pesticides precipitate pest attacks and disease susceptibility, and thus the pesticides induce a cycle of further pesticide use.
Further, the femto-products may include a FemtoMed. Further, the FemtoMed may be made of only atoms 1000 times smaller than nanometer and made of Femto-technology (Electrons, Protons, Neutrons) elements.
Further, the present disclosure describes a composition comprising carbanions. Further, the carbanions are created using picotechnology. Further, the picotechnology works atom to atom for mechanical disassembly of Virus, Bacteria, Insect, and
Fungi control. Further, a single drop of the composition may include 5 sextillion charged atoms. Further, the charged atoms restrict viruses' elemental mode of action by eliminating strands of nucleic acid, either DNA or RNA, and a protective protein
coat (the capsid), or a lipid envelope, surrounding the protein of the viruses.
Further, the present disclosure describes a composition comprising carbanions for treating lung cancer. Further, a dosage of 3 drops of FemtoMed given using a nebulizer for 5 consecutive days includes 75 sextillion carbanions for treating the
lung cancer.
Further, the present disclosure describes a method and a process of creating carbanions that are used as a treatment for contagious and/or infectious viruses are shown. The method and process may include four stages. The process comprises a
mining stage, a mixture stage, a production stage, and a treatment stage. The four different stages define the method and process of creating the carbanion to be used as a treatment for contagious and/or infectious viruses. The mining stage is the
first stage of the method and process in the creation and usage of the carbanions. The mining stage is the initial stage in which the process of gathering and extracting carbon occurs. The gathering and extraction of carbon primarily occur from
different parts of corn plants and tree oils. Some specific materials used in the process of mining are corn and tree oils. Corn has many parts to it such as leaves, stems, grain, roots, and cob. These different parts of corn contain many different
elemental compositions such as carbon, oxygen, hydrogen, nitrogen, phosphorus, potassium, calcium, magnesium, sulfur, iron, silicon, aluminum, chlorine, and manganese. In summary, carbon is obtained through plants by the extraction of carbon dioxide.
The mixture stage is the second stage of the method and process in the creation and usage of the carbanions. The mixture stage is the next stage after the mining stage. In the mixture stage, the blending and mixing of the ingredients along with the
carbon from the mining stage occurs. The said ingredients are mixed in a proprietary sequence and time to create the solution that is ready to go under an exothermic reaction to create the carbanion. The production stage is the third stage of the
method and process in the creation and usage of the carbanions. The production stage is the next stage after the mixture stage. In the production stage, an exothermic chemical reaction occurs to the said solution from the mixture stage. The solution
that is created in the mixture stage is ready to undergo an exothermic reaction in order to produce the carbanion within the solution. An exothermic reaction is a chemical reaction that releases energy through light or heat, in this case, heat is
applied and used. The exothermic reaction causes the carbon atoms within the solution to go from a neutral 6 neutrons, 6 protons, and 6 electrons configuration to a negatively charged 6 neutrons, 6 protons, and 8 electrons carbanion. The exothermic
chemical reaction that is used is a process that robs electrons from other compounds and is given to the carbon atoms thus creating the carbanions. A carbanion has a highly negatively charged organic carbon, trivalent carbon atom that has eight
electrons in its valence shell. The process of adding electrons is done by using temperature or pressure. The treatment stage is the fourth stage of the method and process in the creation and usage of the carbanions. During the treatment stage, the
solution is ready to be used by the user with an infectious virus. The treatment for the user requires the user to be active with ingestion of the solution for over three days. The user is to apply the treatment three times a day, one in the morning,
one in the afternoon, and one at night. Each treatment requires the user to insert three droplets of the solution into a nebulizer containing an ounce of water. The user is then to use the nebulizer to inhale the solution that is mixed with water
within the nebulizer. The nebulizer will fog the carbanion into the lungs at 5 sextillion atoms of carbanion per drop, these carbanion atoms are to mechanically disassemble the vital parts of the virus as the atoms enter the virus. The interaction
between atoms and ions occurs. When the highly charged carbanion is attached to a positive charge just like in nature, it removes the matter at an atom level. Since the user is applying the treatment three times per day for a duration of three days,
approximately a total of 54 sextillion carbanion atoms are used in the process of treating the user with a virus. The carbanion binds to the body of the virus as well as puncture the membrane and drains vital fluids from the virus. The carbanions are
made by using physical chemistry. Physical chemistry is simply the branch of chemistry concerned with interactions and transformation of materials. Unlike other branches, physical chemistry deals with the principles of physics underlying all chemical
interactions, seeking to measure, correlate, and explain the quantitative aspects of reactions. Physical chemistry is the study of how matter behaves on a molecular and atomic level and how chemical reactions occur. Further, the physical chemistry
involves the transformation of carbon into carbanions with an exothermic reaction. The carbanions have been approved by the USDA. Further, the carbanions form a product that is made from biomass and is also biobased. The product is nearly 90% carbon.
The carbanions have been used in the treatment of multiple viruses in the past. Some viruses in which was treated by the use of the carbanions are arenavirus, banana mild mosaic virus, banana virus, bean pod virus, echovirus, hantavirus, influenza
virus, morbillivirus, mosaic cucumber mosaic virus, parainfluenza virus, paramyxovirus, parvovirus B19, poxvirus vaccinia virus, rhinovirus, soybean mosaic virus, banana streak virus, togavirus, varicella-zoster virus, and Yersinia pestis virus.
The carbanions kill viruses by the elimination of strands of nucleic acid, either DNA or RNA, and a protective protein coat (the capsid), or a lipid envelope, surrounding the protein. The reason the carbanions can kill the said viruses is that
viruses are about 125 nanometer in size and the carbanion atoms are only about 340 picometers. But specifically, COVID-19, also known as Coronavirus, is about 200 nanometer in size and the carbanion atoms are only about 340 picometers. The size
difference is immense so that the carbanion can penetrate and invade the interior of the virus to kill it from the inside and attacking the vital points of a virus. The carbanion is a carbon atom in which contains a negative charge. The valence shell
of a negatively charged carbon atom contains 8 electrons. Thus, its octet is complete, and it contains an extra pair of electrons for 8. The negatively charged carbon is in a state of sp3 hybridization. The hybrid orbitals are directed towards the
corners of a tetrahedron. Three of the hybrid orbitals are involved in the formation of single covalent bonds with other atoms while the 5th hybrid orbital contains a lone pair of electrons. Thus, it has a pyramidal structure similar to NH3 molecule.
The carbanion is a carbon that contains eight electrons which are highly reactive intermediate, and they are readily attacked by electrophilic reagents. Carbanion itself is a nucleophile.
The carbanions have had many successes throughout different viruses. The carbanions have been used in the past on many different people on many different viruses and have successfully treated the users.
The treatment using the carbanions has many testimonial occurrences that have fought off many different viruses. The occurrence is one of many cases where the patients were to use the carbanions with a nebulizer, three droplets a day for three
days to treat COVID-19. It is also important to note that the carbanions are able to treat many different viruses due to similar structures since all viruses have similar structures as the carbanions are to enter the membrane of the virus to kill off
vitals of the said virus. Some viruses in which was treated by the use of the carbanions are arenavirus, banana mild mosaic virus, banana virus, bean pod virus, echovirus, hantavirus, influenza virus, morbillivirus, mosaic cucumber mosaic virus,
parainfluenza virus, paramyxovirus, parvovirus B19, poxvirus vaccinia virus, rhinovirus, soybean mosaic virus, banana streak virus, togavirus, varicella-zoster virus, and Yersinia pestis virus. Further, the carbanions may be used for treating diseases
associated with different viruses.
Further, the present disclosure describes C-therapy to facilitates treating of cancer. Unlike traditional radiation, Carbon C- (carbanions) therapy targets cancer with 100 sextillion C-. Since their more exact, higher, and potentially more
effective doses of radiation can be delivered, without causing damage to surrounding healthy tissues. C-therapy fights cancers and minimizes treatment side effects. Further C-therapy also facilitates treating prostate cancer, head and neck cancer, lung
cancer, soft tissue cancer, pediatric cancer, breast cancer, etc.
Further, the present disclosure describes a compound that is used as a treatment for COVID-19 (coronavirus). Further, the compound may be an organic compound. Further, the compound is created by making use of the carbanion's physical
chemistry. Further, the compound may be used for treating viral infections. Further, the compound is created by taking carbon atoms out of a plant and using temperature to create reduction or redox to add 2 electrons to the carbon atom generating the
highly negatively charged organic carbon atoms. Further, the highly negatively charged organic carbon atoms puncture the membrane of the virus to release vital fluid which causes the virus to die.
Further, the present disclosure describes an organic compound that is used to treat and cure lung diseases caused by viruses, bacteria, or of the likes. Further, the present disclosure describes the use of carbanion's physical chemistry in the
creation of a compound that is used as a lungs bacterial treatment for bacterial, fungus, virus, and diseases related to the lungs. Further, the highly negative charged organic carbon atoms of the organic compound puncture the membrane of the organism
such as bacteria, fungi, etc.
Further, the present disclosure describes a compound that is used to treat and cure skin diseases. Further, the compound may be an organic compound. Further, the compound is created by making use of the carbanion's physical chemistry.
Further, the compound may be used as a skin treatment/cure for skin diseases. Further, the compound is created by taking carbon atoms out of a plant and using temperature to create reduction or redox to add 2 electrons to the carbon atom generating the
highly negatively charged organic carbon atoms. Further, the highly negative charged organic carbon atoms of the organic compound puncture the membrane of the organism such as bacteria, fungi, etc.
Further, the present disclosure relates to physical chemistry. Further, the present disclosure describes a method, process, and usage of creating a carbanion that is used as a treatment for contagious and/or infectious viruses.
Further, the present disclosure describes a treatment for contagious and infectious viruses. The present disclosure also describes a method and process of creating a carbanion as well as the unique usage of the carbanion as a treatment for
contagious and/or infectious viruses. Furthermore, the present disclosure describes a cheap and cost-efficient treatment for contagious and/or infectious viruses. The present disclosure also describes a treatment to cure multiple known viruses and
potentially undiscovered viruses.
FIG. 1 is a table 100 listing ingredients of a medicine composition for facilitating treating organs of a mammal, in accordance with some embodiments. Further, the table 100 may include a column 102 and two rows 104-106. Further, the table 100
may include two cells (column 102, row 104) and (column 102, row 106). Further, the medicine composition may include carbanions and a diluting agent.
Further, a cell (column 102, row 104) of the table 100 may be related to the carbanions. Further, a carbanion of the carbanions may include a carbon atom. Further, the carbon atom may include a formal charge of -1.
Further, a cell (column 102, row 106) of the table 100 may be related to the diluting agent. Further, the diluting agent may be capable of combining with the carbanions for forming at least one appliable form of the medicine composition.
Further, the diluting agent may include at least one solvent. Further, the at least one solvent may include water, cream, oil, etc. Further, a ratio of the diluting agent to the carbanions by volume ranges from 512:1 to 32:1. Further, the combining
facilitates applying of the at least one appliable form of the medicine composition to at least one organ of the mammal. Further, the at least one organ may include lungs, skin, etc. Further, the mammal may include a human. Further, the at least one
appliable form of the medicine composition may include a solution, a suspension, an aerosol, an emulsion, etc.
Further, in some embodiments, the ratio of the diluting agent to the carbanions by the volume may be 284:1.
Further, in some embodiments, the ratio of the diluting agent to the carbanions by the volume may be 189:1.
Further, in some embodiments, the ratio of the diluting agent to the carbanions by the volume may be 57:1.
In further embodiment, the medicine composition may include an elemental composition in a ratio to the carbanions by volume. Further, the ratio of the elemental composition to the carbanions by the volume may be 1:9. Further, in an embodiment,
the elemental composition may include oxygen, hydrogen, nitrogen, phosphorus, potassium, calcium, magnesium, sulfur, iron, silicon, aluminum, chlorine, and manganese.
Further, in some embodiments, each carbanion of the carbanions may be capable of creating an electromechanical reaction with an organic material of at least one organism present on the at least one organ of the mammal based on the applying of
the at least one appliable form of the medicine composition. Further, the creating of the electromechanical reaction disassembles the organic material of the at least one organism for eliminating the at least one organism. Further, the eliminating of
the at least one organism facilitates the treating of the at least one organ of the mammal. Further, the at least one organism may include viruses, bacteria, fungi, protozoa, insects, etc. Further, the insects may include pests, parasites, etc. Further,
the organic material of the at least one organism may include lipid, protein, etc. Further, the at least one organism causes at least one disease to the at least one organ. Further, the at least one disease may include lung diseases, skin diseases, etc.
Further, the lung diseases may include COVID-19. Further, the skin disease may include gangrene.
Further, in some embodiments, the carbanions may be derived from at least one organic material. Further, the at least one organic material may be associated with at least one part of at least one plant. Further, the at least one plant may
include a corn plant. Further, the at least one part of the corn plant may include a leaf, a stem, a grain, a root, and a cob.
Further, in some embodiments, the diluting agent may include at least one cream. Further, the at least one cream may include a shea butter.
Further, in some embodiments, the diluting agent may include at least one moisturizing element.
FIG. 2 is a flowchart of a method 200 for facilitating treating organs of a mammal using a medicine composition, in accordance with some embodiments. Further, at 202 the method 200 may include a step of transforming, using at least one
application device, the medicine composition into at least one appliable form. Further, the medicine composition may include carbanions and a diluting agent. Further, a carbanion of the carbanions may include a carbon atom. Further, the carbon atom
may include a formal charge of -1. Further, the diluting agent may be capable of combining with the carbanions for forming the at least one appliable form of the medicine composition. Further, the at least one appliable form of the medicine composition
may include a solution, a suspension, an aerosol, an emulsion, etc. Further, a ratio of the diluting agent to the carbanions by volume ranges from 512:1 to 32:1.
Further, at 204, the method 200 may include a step of applying, using the at least one application device, at least one dosage of the at least one appliable form of the medicine composition on at least one organ of the mammal based on the
transforming. Further, the applying of the at least one dosage of the at least one appliable form of the medicine composition facilitates the treating of the at least one organ of the mammal. Further, the at least one organ may include lungs, skin,
etc. Further, the mammal may include a human.
Further, in some embodiments, the at least one application device may include a nebulizer. Further, the at least one organ may include at least one lung. Further, the at least one appliable form of the medicine composition may include an
aerosol. Further, the transforming may include aerosolizing the medicine composition into the aerosol. Further, the applying may include delivering the aerosol to the at least one lung of the mammal.
Further, in some embodiments, the at least one application device may include an emulsifier. Further, the at least one organ may include skin. Further, the at least one appliable form of the medicine composition may include an emulsion.
Further, the transforming may include emulsifying the medicine composition into the emulsion. Further, the applying may include covering the skin of the mammal with the emulsion.
In further embodiments, the method 200 may include a step of generating, using the at least one application device, the at least one dosage of the at least one appliable form of the medicine composition. Further, the applying of the at least
one dosage of the at least one appliable form of the medicine composition may be based on the generating of the at least one dosage.
Further, in some embodiments, the at least one dosage of the at least one appliable form of the medicine composition may include one ounce of water and at least three drops of the carbanions. Further, the diluting agent may include the water.
Further, one drop of the carbanions may include 5 sextillion carbon atoms. Further, one ounce may include 353 drops.
Further, in some embodiments, the treating of the at least one organ may include eliminating at least one organism from the at least one organ causing at least one disease in the at least one organ of the mammal based on the applying. Further,
the eliminating may include disassembling an organic material of the at least one organism based on an interaction of the carbanions with the organic material based on the applying. Further, the at least one organism may include viruses, bacteria,
fungi, protozoa, insects, etc. Further, the insects may include pests, parasites, etc. Further, the organic material of the at least one organism may include lipid, protein, etc. Further, the at least one organism causes at least one disease to the at
least one organ. Further, the at least one disease may include lung diseases, skin diseases, etc. Further, the lung diseases may include COVID-19. Further, the skin disease may include gangrene.
Further, in some embodiments, the treating of the at least one organ may include regenerating at least one tissue of the at least one organ of the mammal based on the applying. Further, the at least one disease causes degeneration of the at
least one tissue of the at least one organ.
Further, in some embodiments, the at least one dosage of the at least one appliable form of the medicine composition may be associated with a dosing frequency. Further, the dosing frequency may include three times a day for at least one three
days. Further, the applying of the at least one dosage of the at least one appliable form of the medicine composition with the dosing frequency facilitates the treating of the at least one organ.
Further, in some embodiments, the applying of the at least one appliable form of the medicine composition may be associated with an applying duration. Further, the at least one applying duration may include at least one minute, at least one
hour, etc. Further, the treating of the at least one organ may be based on the applying of the at least one appliable form of the medicine composition for the applying duration.
Further, in some embodiments, the at least one appliable form of the medicine composition may include a solution. Further, the solution may be appliable to the at least one organ using at least one application method. Further, the at least one
application method may include soaking, washing, inhaling, gargling, rinsing, etc. Further, the applying of the solution of the medicine composition to the at least one organ facilitates the treating of the at least one organ.
FIG. 3 is an illustration of carbanions 300 of the medicine composition, in accordance with some embodiments. Further, the carbanions 300 may be derived from at least one organic material source. Further, the at least one organic material
source may include at least one plant. Further, the carbanions 300 may include carbon atoms extracted from the at least one plant. Further, the carbanions 300 may include a 100% organic matter. Further, the organic matter may be organic carbon atoms.
Further, at least one of a specific temperature and a specific pressure may be applied to the carbon atoms for initiating at least one of a reduction reaction and a redox reaction. Further, the at least one of the reduction reaction and the redox
reaction adds 2 electrons to the carbon atoms for creating negatively charged carbon atoms. Further, each negatively charged carbon atom of the negatively charged carbon atoms may include 8 electrons and 6 protons, and 6 neutrons. Further, the
negatively charged carbon atoms may be highly negatively charged. Further, the negatively charged carbon atoms may be the carbanions 300. Further, the carbanions 300 may include a trivalent carbon atom comprising eight (8) electrons in the valence
shell of the trivalent carbon atom. Further, the carbanions 300 may be created using physical chemistry of the carbanions 300. Further, the carbanions 300 may include micelles structures. Further, the micelles structure may include a spherical shape.
FIG. 4 is a front view of a container 400 containing the medicine composition, in accordance with some embodiments. Further, the medicine composition may include the carbanions and the diluting agent. Further, the medicine composition may be
configured for treating the organs of the mammal. Further, the organs may have at least one disease. Further, the treating may include curing the at least one disease associated with the organs. Further, the organs may include lungs, skin, etc. of the
mammal. Further, the mammal may include a human and an animal. Further, the at least one disease may include lung diseases, skin diseases, etc. Further, the lung diseases may include COVID-19. Further, the skin diseases may include gangrene. Further,
at least one of fungi, bacteria, viruses, and insects may cause the at least one disease. Further, the insects may include pests, parasites, etc. Further, the carbanions may be derived from at least one organic source. Further, the at least one organic
source may include at least one plant. Further, the carbanions may include 100% organic matter. Further, the organic matter may include organic carbon atoms. Further, the carbanions may include carbon atoms. Further, the carbon atoms may be extracted
from the at least one plant. Further, at least one of a specific temperature and a specific pressure may be applied to the carbon atoms for initiating at least one of a reduction reaction and a redox reaction. Further, the initiating of the at least
one of the reduction reaction and the redox reaction may add 2 electrons to the carbon atoms creating negatively charged carbon atoms. Further, each negatively charged carbon atom of the negatively charged carbon atoms may include 8 electrons and 6
protons, and 6 neutrons. Further, the negatively charged carbon atoms may be highly negatively charged. Further, the negatively charged carbon atoms may be the carbanions. Further, the carbanions may include a trivalent carbon atom comprising eight
(8) electrons in the valence shell of the trivalent carbon atom. Further, the negatively charged carbon atoms may be created using the physical chemistry of the carbanions. Further, the negatively charged carbon atoms may be configured for puncturing
the membrane of the at least one of the fungi, the bacteria, the viruses, and the insects. Further, the puncturing of the membrane makes the at least one of the fungi, the bacteria, the viruses, and the insects may eliminate the at least one of the
fungi, the bacteria, the viruses, and the insects. Further, the puncturing of the membrane makes the at least one of the fungi, the bacteria, the viruses, and the insects inactive and facilitates treating the organs.
Further, in some embodiments, the puncturing of the membrane of the at least one of the fungi, the bacteria, the viruses, and the insects may release vital fluids of the at least one of the fungi, the bacteria, the viruses, and the insects.
Further, the release of the vital fluids may cause the death of the at least one of the fungi, the bacteria, the viruses, and the insects making the at least one of the fungi, the bacteria, the viruses, and the insects inactive. Further, the death of
the at least one of the fungi, the bacteria, the viruses, and the insects may facilitate the treating of the organs.
Further, in some embodiments, the at least one disease may include bacterial diseases associated with the bacteria. Further, the organs may have the bacterial diseases Further, the bacterial diseases may include Bronchitis, Chronic Cough,
Common Cold, Influenza, Pertussis, Pleurisy, Pneumonia, Sarcoidosis, Spirometry, Sudden Infant Death Syndrome (SIDS), Tuberculosis, actinomycosis, Anthrax, boutonneuse fever, brucellosis, brucellosis spondylitis, campylobacteriosis, Carrion disease, cat
scratch disease, cervicitis, chancroid, chlamydia, lymphogranuloma venereum, cholera, clostridial infection, dysentery, shigellosis, epididymitis, erysipelothrix infection, glanders, gonorrhea, granuloma inguinale, Legionnaire disease, Leprosy,
leptospirosis, listeriosis, Lyme disease, Melioidosis, nocardiosis, paratyphoid fever, pharyngitis, plague, bubonic plague, pneumonia, proctitis, pseudotuberculosis, psittacosis, Q fever, rat-bite fever, Reiter syndrome, relapsing fever, rheumatic fever,
Rocky Mountain spotted fever, Salmonellosis, scarlet fever, septicemia, Waterhouse-Friderichsen syndrome, Shigellosis, streptobacillary fever, syphilis, bejel, gumma, yaws, tetanus, tonsillitis, toxic shock syndrome, trench fever, tuberculosis, scrofula,
tularemia, typhoid fever, typhus, scrub typhus, urethritis, vaginitis, vesiculitis, vulvitis, whooping cough, yersiniosis, etc.
Further, in some embodiments, the at least one disease may include fungal diseases associated with the fungi. Further, the organs may have the fungal diseases. Further, the fungal diseases may include Aspergillosis, Cryptococcosis,
Candidiasis, Mucormycosis, Pneumocystis jirovecii Pneumonia, aspergillosis, Blastomycosis, candidiasis, thrush, chromoblastomycosis, coccidioidomycosis, cryptococcosis, histoplasmosis, pharyngitis, pneumonia, sporotrichosis, urethritis, vaginitis,
vulvitis, etc.
Further, in some embodiments, the at least one disease may include protozoa diseases associated with protozoa. Further, the organs may have the protozoa diseases. Further, the protozoa diseases may include avian malaria, Chagas disease,
Coccidiosis, leishmaniasis, Oriental sore, Malaria, blackwater fever, sleeping sickness, toxoplasmosis, trichomoniasis, trypanosomiasis, etc
Further, in some embodiments, the treating of the lungs and the curing of the lung diseases may include an application of the medicine composition to the lungs. Further, the application may include at least one of inhaling, gargling, drinking,
etc. Further, the application may be associated with at least one duration. Further, the at least one duration may include at least one second, at least one minute, at least one hour, etc. Further, the application may be repeated after at least one
second duration of at least one first duration. Further, the at least one first duration may include at least one first minute, at least one first hour, at least one first day. Further, the at least one second duration may include at least one second
minute, at least one second hour, at least one second day. Further, in an embodiment, the application may include at least three applications in a day for three days. Further, each application of the at least three applications may include a dosage of
the carbanions. Further, the dosage may include 2 to 10 drops. Further, 1 drop may include 5 sextillion carbanions. Further, the 2-10 drops may include 10 to 50 sextillion carbanions.
Further, in some embodiments, the medicine composition may be administered using a nebulizer. Further, the nebulizer may use a solution of the medicine composition. Further, the solution may include at least three drops of the carbanions mixed
with an ounce of the water. Further, the nebulizer may turn the solution into a mist for inhaling the solution. Further, the at least one of the humans and the animals may inhale the mist. Further, the inhaling of the mist may facilitate the treating
of the organs and the curing of the diseases. Further, the inhaling of the solution three times a day for at least three days facilitate the treating and the curing. Further, one drop of the carbanions may include 5 sextillion carbon atoms. Further,
one ounce may include 353 drops.
Further, in some embodiments, the treating of the skin and the curing of the skin diseases may include an application of the medicine composition on the skin. Further, the application may include at least one of rubbing, massaging, coating,
soaking, washing, spraying, etc. Further, the application may be associated with at least one duration. Further, the at least one duration may include at least one second, at least one minute, at least one hour, etc. Further, the application may be
repeated after at least one second duration of at least one first duration. Further, the at least one first duration may include at least one first minute, at least one first hour, at least one first day. Further, the at least one second duration may
include at least one second minute, at least one second hour, at least one second day.
Further, in some embodiments, the treating of the skin and the curing of the skin diseases may include regenerating the skin of at least one body part of the human. Further, the at least one of the treating and the curing may include growing of
the skin on the at least one body part.
Further, in some embodiments, the skin diseases may be associated with skin conditions of the skin. Further, the skin conditions may include burns, acne, infections of the skin. Further, a FemtoMed comprising the medicine composition may be
used to prevent infection in second and third-degree burns. Further, FemtoMed may be sprayed on the burns affected areas of the skin multiple times per day. Further, the FemtoMed may be applied on the acne-affected areas of the skin. Further, the
FemtoMed may reduce skin oil and kill infections. Further, the infection on the skin may include bacterial infections, fungal infections, yeast, viral, Ricketsial, and chemical burns. Further, the FemtoMed may cure the infection on the skin.
Further, in some embodiments, the medicine composition may be used in a cream. Further, the cream may be applied twice a day for two days. Further, the cream may include Shea butter. Further, twice the day may include a morning time and a bed
time. Further, each of the morning time and the bed time may be associated with a dosage of the carbanions. Further, the dosage may include 1/3 oz. Further, 1 oz may include 353 drops. Further, the 1/3 oz may be 118 drops. Further, 1 drop may
include 5 sextillion carbanions. Further, the 118 drops may include 590 sextillion carbanions.
Further, in some embodiments, a "FemtoMed" comprising the medicine composition. Further, the "FemtoMed" may be a 100% concentrate in liquid or cream. Further, the "FemtoMed" may be a 100% concentrate made of US
Government FDA EAFUS food additives. Further, the "FemtoMed" may be like a single element, not a chemical compound. Further, the "FemtoMed" may be safe for ingestion and inhalation. Further, the "FemtoMed" may be applied to the
internal and external skin of the at least one body part. Further, the "FemtoMed" may be cosmetic moisturizer for skin issues of debriding, cleansing wash, to promote healing and or pain relief. Further, the "FemtoMed" may be used for
skin issues of skin softening, bio-films, crust, scab, divots, fungal, molds, sun-spots, granules, inflammation, lesions, ulcers, itchy, skin loss, oozing, sores, wounds, pigment changes, pimples, rashes, scabbing, shards, leathery skin, callus, and dry
skin. Also, it helps with skin sensations of biting, burning, crawling, creeping, itching, pricking, pinching, and stinging. Further, the "FemtoMed" may be available as a liquid or cream product.
Further, in an embodiment, the skin diseases may include Genetic Blistering, Dog Ear Infection, Lamb Gangrene Infection, MRSA, Psoriasis, Squamous Cancer, Arm Dandruff, Ringworms, Whooping Cough Pneumonia, Parasite Scabies, Basal Cell Cyst,
Cellulitis, Head Lice, Lupus, etc. Further, the "FemtoMed" may facilitate the treating of the skin and the curing of the skin diseases.
Further, in an embodiment, the skin diseases may include gangrene. Further, the gangrene may be associated with the at least one body part. Further, the gangrene may be a potentially life-threatening condition that arises when a considerable
mass of body tissue dies (necrosis). Further, the gangrene may occur after an injury or infection, or in people suffering from any chronic health problem affecting blood circulation. Further, the primary cause of gangrene may be reduced blood supply to
the affected tissues, which results in cell death. Further, the gangrene may be caused by ischemia or infection, such as by the bacteria Clostridium perfringens or by thrombosis (a blood vessel blocked by a blood clot). Further, the gangrene may be
usually the result of critically insufficient blood supply (e.g., peripheral vascular disease) and may be often associated with diabetes and long-term tobacco smoking. Further, the gangrene may be most common in the lower extremities (such as the leg).
The best medical treatment today for the gangrene may be revascularization (i.e., restoration of blood flow) of the afflicted organ, which can reverse some of the effects of necrosis and allow healing. Further, the other treatment of the gangrene may
include debridement and surgical amputation. Further, the method of treatment may be generally determined by the location of affected tissue and the extent of tissue loss.
Further, the treatment of the gangrene may include applying a moisturizer. Further, the moisturizer may be made up of 90% of 600 (Picometer) carbon particles. Further, the treatment may eliminate the gangrene. Further, the treatment may
eliminate the wound of the gangrene. Further, the treatment may make the skin grow from the edges to the center of the gangrene wound. Further, the treatment may cure the gangrene without the reduction of body parts affected by the gangrene. Further,
the gangrene may cause the Gangrene Black on the body parts. Further, the application of "FemtoMed" may remove the Gangrene Black. Further, the "FemtoMed" may include the carbanions. Further, the application of the "FemtoMed"
starts the process of skin growth on the body parts. Further, the application of the "FemtoMed" for at least three days may cause a 100% reduction in the black Gangrene part on foot. Further, the application of the "FemtoMed" may cause
growth in the tissue on an upper part of the foot. Further, the application of the "FemtoMed" may cause the skin to grow and reverse the damage caused by the gangrene on the foot. Further, the application of the "FemtoMed" may include 4
oz per gallon dilution. Further, the application may include three foot-baths daily for 30 min. Further, the application may cause the forming of tan-colored covering. Further, the tan-colored forming may be mucoid exudate that forms on the healing of
a full thickness wound of the gangrene. Further, skin form over an entire surface at one time other than skin cells being sprayed onto a matrix placed on a skinless wound. Further, the "FemtoMed" may replace the traditional treatment of the
gangrene. Further, the traditional treatment may include surgical debridement, wound care, and antibiotic therapy, and amputation is necessary in many cases. Further, the amputation may be performed for an ischemic disease of the lower extremity. Of
dysvascular amputations, 15-28% of patients undergo contralateral limb amputations within 3 years. Of elderly persons who undergo amputations, 50% survive the first 3 years. Further, the treatment using the "FemtoMed" may cure the gangrene
without performing the amputation.
Further, the "FemtoMed" may be used for treating the gangrene. Further, the treating may eliminate the gangrene without the amputation of the affected body part (such as legs). Further, the "FemtoMed" may be used in 4 oz per
gallon dilution. Further, the treating of the gangrene may include at least three applications of the "FemtoMed" to the leg for at least thirty minutes. Further, the treating of the gangrene may include removal of gangrene black of the leg,
growth in the skin of the leg, and formation of tissue on the leg.
Further, in some embodiments, the carbanions may control gram-positive bacteria at 16,000 of the water to 1. Further, the carbanions may control the gram-positive bacteria at 1 ml to 16 liters of water.
Further, in some embodiments, a carbanion of the carbanions may be an anion in which carbon bears a formal negative charge. Further, the carbanion may include eight electrons in the valence shell of the carbon. Further, a carbon-atom of the
carbanion may include a negative charge. Further, the valence shell of a negatively charged carbon atom may include 8-electrons. Further, the octet of the negatively charged carbon atom may be complete. Further, the negatively charged carbon atom may
include an extra pair of electrons. Further, the negatively charged carbon atom may be in a state of sp3 hybridization. Further, the hybrid orbitals may be directed towards the corners of a tetrahedron. Further, three hybrid orbitals may be involved
in the formation of single covalent bonds with other atoms while the fourth hybrid orbital may include a lone pair of electrons. Further, the carbanion may include a pyramidal structure similar to NH3 (Ammonia) molecule. Further, the carbon-atom may
include eight electrons. Further, the carbon-atom may be a highly reactive intermediate. Further, the carbon-atom may be readily attacked by electrophilic reagents. Further, the carbanion may be a nucleophile.
Further, the carbanion may include "Negative Octet Energy". Further, the carbanion may be an anion in which the carbon-atom bears a formal negative charge. Further, in an embodiment, the carbanion may include a single negatively charged carbon
atom. Further, the single negatively charged carbon atom bonds to no other atoms except for another single negatively charged carbon atom.
FIG. 5 is a plot of light scattering by the carbanions through a dynamic light scattering, in accordance with some embodiments. Further, the dynamic light scattering may be a technique for measuring a particle size. Further, the particle size
range from a few nanometers (nm) to a few microns. Further, the light intensity may be proportional to the size of "aggregates". Further, the dynamic light scattering may be an excellent tool for translocation. Further, 0.6 nm peaks may show greater
intensity-weight distribution. Further, large aggregates scatter the storing light for 0.6 nm peak. Further, most micelles may be 0.6 nm in particle size hydrodynamic radius.
FIG. 6 is a magnified view of a sample of a solution of the medicine composition, in accordance with some embodiments. Further, the solution may include a 1:1 dilution. Further, the sample of the solution may be magnified up to 100,000.times.. Further, the sample of the solution may include droplets with small grains. Further, the droplets may include the carbanions.
FIG. 7 is a magnified view of a sample of the solution, in accordance with some embodiments. Further, the solution may include a 1:1 dilution. Further, the sample of the solution may be magnified up to 100,000.times.. Further, the sample of
the solution may include droplets with small grains. Further, the droplets may include the carbanions.
FIG. 8 is a magnified view of a sample of a solution of the medicine composition, in accordance with some embodiments. Further, the solution may include a 1:100 dilution. Further, the sample of the solution may be magnified up to
100,000.times.. Further, the sample of the solution may include droplets with small grains. Further, the droplets may include the carbanions.
FIG. 9 is a magnified view of a sample of the solution, in accordance with some embodiments. Further, the solution may include a 1:100 dilution. Further, the sample of the solution may be magnified up to 100,000.times.. Further, the sample of
the solution may include droplets with small grains. Further, the droplets may include the carbanions.
FIG. 10 is a magnified view of a sample of a solution of the medicine composition, in accordance with some embodiments. Further, the solution may include a straight solution. Further, the solution may be magnified up to 100,000.times..
Further, the sample of the solution may include droplets. Further, the droplets may include similar size particles around the edges, but inside, the grain is less than 1 nm (nanometer). Further, the droplets may include the carbanions.
FIG. 11 is a schematic of a carbanion 1100 of the carbanions, in accordance with some embodiments. Further, the carbanion 1100 is an anion in which carbon bears a formal negative charge. Further, the carbanion 1100 may include eight electrons
in the valence shell of the carbon. Further, a carbon-atom of the carbanion 1100 may include a negative charge. Further, the valence shell of a negatively charged carbon-atom may include 8-electrons. Further, the octet of the negatively charged carbon
atom may be complete. Further, the negatively charged carbon atom may include an extra pair of electrons. Further, the negatively charged carbon may be in a state of sp3 hybridization. Further, the hybrid orbitals may be directed towards the corners
of a tetrahedron. Further, three of the hybrid orbitals may be involved in the formation of single covalent bonds with other atoms while the fourth hybrid orbital may include a lone pair of electrons. Further, the carbanion 1100 may include a pyramidal
structure similar to NH3 molecule. Further, the carbon-atom may include eight electrons even the carbon-atom may be a highly reactive intermediate. Further, the carbon-atom may be readily attacked by electrophilic reagents. Further, the carbanion 1100
may be a nucleophile.
FIG. 12 is an illustration of gram-positive bacteria. Further, the gram-positive bacteria retain crystal violet dye and stain dark violet or purple. Further, the gram-positive bacteria remain blue or purple colored with gram stain when washed
with absolute alcohol and water. Further, the gram-positive bacteria may include a thick (multilayered) Peptidoglycan layer. Further, Teichoic acids may be present in most of the gram-positive bacteria. Further, Periplasmic space is absent in the
gram-positive bacteria. Further, an outer membrane is absent in the gram-positive bacteria. Further, Lipopolysaccharide (LPS) content is virtually absent in the gram-positive bacteria. Further, the gram-positive bacteria may include low Lipid and
lipoprotein content. Further, acid-fast bacteria may have lipids linked to peptidoglycan. Further, the gram-positive bacteria may primarily produce Exotoxins. Further, a flagellar structure of the gram-positive bacteria may include 2 rings in the
basal body. Further, the gram-positive bacteria may have high resistance to physical disruption. Further, the gram-positive bacteria may have high inhibition by basic dyes. Further, the gram-positive bacteria may have a high susceptibility to anionic
detergents. Further, the gram-positive bacteria may have high resistance to sodium azide. Further, the gram-positive bacteria may have high resistance to drying. Further, the cell wall of the gram-positive bacteria is 100-120 .ANG. thick and
single-layered. The lipid content of the cell wall is low, whereas Murein content is 70-80% (higher). Further, Mesosome is more prominent in the gram-positive bacteria. Further, the gram-positive bacteria are more susceptible to antibiotics.
FIG. 13 is an illustration of gram-negative bacteria. Further, the gram-negative bacteria may be decolorized to accept counterstain (Safranin or Fuchsine) to stain red or pink. Further, the gram-negative bacteria do not retain the Gram stain
when washed with absolute alcohol and acetone. Further, the gram-negative bacteria may include a thin (single-layered) Peptidoglycan layer. Further, Teichoic acids are absent in most of the gram-negative bacteria. Further, Periplasmic space is present
in gram-negative bacteria. Further, an outer membrane is present in the gram-negative bacteria. Further, Lipopolysaccharide (LPS) content is high in the gram-negative bacteria. Further, the gram-negative bacteria may include a high lipid and
lipoprotein content due to the presence of the outer membrane. Further, the gram-negative bacteria may primarily produce Endotoxins. Further, a flagellar structure of the gram-negative bacteria may include 4 rings in the basal body. Further, the
gram-negative bacteria may have a low resistance to physical disruption. Further, the gram-negative bacteria may have low inhibition by basic dyes. Further, the gram-negative bacteria may have low susceptibility to anionic detergents. Further, the
gram-negative bacteria may have a low resistance to sodium azide. Further, the gram-negative bacteria may have a low resistance to drying. Further, the cell wall of the gram-negative bacteria is 70-120 .ANG. (angstrom) thick and two-layered. Further,
Lipid content is 20-30% (high) and Murein content is 10-20% (low). Further, Mesosome is less prominent in the gram-negative bacteria. Further, the gram-negative bacteria are more resistant to antibiotics.
Further, the gram-positive bacteria and the gram-negative bacteria are differentiated based on the structural differences in cell walls of the gram-positive bacteria and the gram-negative bacteria. Gram-positive bacteria retain the crystal
violet dye do so because of a thick layer of peptidoglycan. In contrast, Gram-negative bacteria do not retain the violet dye and are colored red or pink. Compared with Gram-positive bacteria, Gram-negative bacteria are more resistant against antibodies
because of the impenetrable cell wall. Further, the gram-positive bacteria and the gram-negative bacteria have a wide variety of applications ranging from medical treatment to industrial use and Swiss cheese production.
Further, the microscopic view of dental plaque shows Gram-positive bacteria (purple) and gram-negative bacteria (red). Further, in a Gram stain test, the gram-positive bacteria and the gram-negative bacteria are washed with a decolorizing
solution after being dyed with crystal violet. On adding a counterstain such as safranin or fuchsine after washing, Gram-negative bacteria are stained red or pink while Gram-positive bacteria retain crystal violet dye. This is due to the difference in
the structure of the bacterial cell wall of the gram-positive bacteria and the gram-negative bacteria. Gram-positive bacteria do not have an outer cell membrane found in Gram-negative bacteria. The cell wall of Gram-positive bacteria is high in
peptidoglycan which is responsible for retaining the crystal violet dye.
Further, both gram-positive bacteria and gram-negative bacteria may be pathogenic. Further, six gram-positive genera of bacteria are known to cause disease in humans: Streptococcus, Staphylococcus, Corynebacterium, Listeria, Bacillus, and
Clostridium. Another three cause diseases in plants: Rathybacter, Leifsonia, and Clavibacter. Many gram-negative bacteria are also pathogenic e.g., Pseudomonas aeruginosa, Neisseria gonorrhoeae, Chlamydia trachomatis, and Yersinia pestis.
Gram-negative bacteria are also more resistant to antibiotics because the outer membrane may include a complex lipopolysaccharide (LPS) whose lipid portion acts as an endotoxin.
Further, a lot of Gram-negative bacteria are resistant to a number of important antibiotics that are used to treat the gram-negative bacteria. Further, agents like Acinetobacter, Pseudomonas, E. coli. Further, the gram-negative bacteria have
very quickly developed resistance to antibiotics. Gram-negative agents becoming very rapidly more and more resistant to all of the agents. Greater resistance of gram-negative bacteria also applies to a newly discovered class of antibiotics. Further,
the drugs are not likely to work on gram-negative bacteria. Further, bacteria are classified based on the cell shape into bacilli (rod-shaped) and cocci (sphere-shaped). Typical Gram-positive cocci stains include Clusters: usually characteristic of
Staphylococcus, such as S. aureus, Chain: usually characteristic of Streptococcus, such as S. pneumoniae, B group streptococci, Tetrad: usually characteristic of Micrococcus.
Further, gram-positive bacilli tend to be thick, thin, or branching.
Further, many streptococcal species are nonpathogenic and form part of the commensal human microbiome of the mouth, skin, intestine, and upper respiratory tract. Further, the streptococcal species is also a necessary ingredient in producing
Emmentaler (Swiss) cheese. Non-pathogenic species of corynebacterium are used in the industrial production of amino acids, nucleotides, bioconversion of steroids, degradation of hydrocarbons, cheese aging, production of enzymes, etc. Many Bacillus
species are able to secrete large quantities of enzymes. Bacillus amyloliquefaciens is the source of a natural antibiotic protein barnase (a ribonuclease), alpha amylase used in starch hydrolysis, the protease subtilisin used with detergents, and the
BamH1 restriction enzyme used in DNA research. C. thermocellum may utilize lignocellulose waste and generate ethanol, thus making it a possible candidate for use in the production of ethanol fuel. It is anaerobic and is thermophilic, which reduces
cooling costs. C. acetobutylicum, also known as the Weizmann organism, was first used by Chaim Weizmann to produce acetone and biobutanol from starch in 1916 for the production of gunpowder and TNT. C. botulinum produces a potentially lethal neurotoxin
that is used in a diluted form in the drug Botox. It is also used to treat spasmodic torticollis and provides relief for approximately 12 to 16 weeks. The anaerobic bacterium C. ljungdahlii may produce ethanol from single-carbon sources including
synthesis gas, a mixture of carbon monoxide, and hydrogen that may be generated from the partial combustion of either fossil fuels or biomass. Gram-indeterminate and Gram-variable Bacteria
Not all bacteria may be reliably classified through Gram staining. For example, acid-fast bacteria or Gram-variable do not respond to Gram staining.
FIG. 14 is an illustration of an effect of NG 1 on Alternaria alternata, in accordance with some embodiments.
FIG. 15 is an illustration of an effect of NG 2 on Sclerotium rolfsii, in accordance with some embodiments.
FIG. 16 is an illustration of an effect of NG 1 on Macrophomina phaseolina, in accordance with some embodiments.
FIG. 17 is a table 1700 of an initial screen of pathogens vs. dilution of Formula S-101, in accordance with some embodiments. Further, the initial screen may include results at 96 hours after treatment for 22 hours. Further, the Formula S-101
may include the carbanions. Further, the initial screen may be associated with an evaluation of Formula S-101 and S-102 for activity against gram-positive plant pathogenic bacteria using Femtotechnology 340 pm/600 pm.
Further, Femtotechnology 340 pm/600 pm Evaluation of Formula S-100 was effective in vitro at multiple concentrations in killing multiple isolates of agriculturally important Gram-positive plant pathogens. The bacteria tested in these assays
were Clavibacter michiganensis subsp. nebraskensis (causal agent of Goss's wilt and blight of maize), CI. mich. subsp. michiganensis (causal agent of bacterial canker of tomato), CI. mich. subsp. insidiosus (causal agent of bacterial wilt of
alfalfa), and Curtobacterium flaccumfaciens pv. flaccumfaciens (causal agent of bacterial wilt of dry bean). The three subspecies of Clavibacter michiganensis tested had indistinguishable sensitivities to Formula S-100 after 22 hours treatment
(2.sup.-14= 1/16384, or 61 ppm), while Curtobacterium flaccumfaciens pv. flaccumfaciens was much less sensitive (2.sup.-8= 1/256, or 3.9 ppt). One replicate of a subset of strains was tested after 2 hours of treatment; this shorter exposure time was
nearly as effective as 22 hours. Further, Formula S-100 was tested in vitro at multiple concentrations to assess its potential efficacy as a protection agent against important Gram-positive plant pathogenic bacteria in a greenhouse and field-grown
crops. Further, materials and methods associated with the evaluation may include test organisms. Further, the test organisms may include Clavibacter michiganensis subsp. nebraskensis (Cmn) Disease: Goss' wilt and blight of maize. Further, the test
organisms may include Clavibacter michiganensis subsp. michiganensis (Cmm) Disease: bacterial canker of tomato. Further, the test organisms may include Clavibacter michiganensis subsp. insidiosus (Cmi) Disease: bacterial wilt of alfalfa. Further, the
test organisms may include Curtobacterium flaccumfaciens pv. flaccumfaciens (Cff) Disease: bacterial wilt of dry bean.
Further, Bacterial cultures had been maintained as lyophilized cultures or in Microbank vials (PRO-LAB Diagnostics, Canada) at -70.degree. C. Culture suspensions, made from colonies grown on Tryptic Soy Agar, were grown for two to three hours
in 10 ml Tryptic Soy Broth (Difco, Sparks, MD) at 27.degree. C., sessile. The optical density of each culture was determined spectrophotometrically at 640.
Further, tested in this assay was the Formula S-100 non-toxic surfactant an amber and a viscous solution. Further, a modified Minimal Inhibitory Concentration (MIC) microbiological assay was used to determine levels of resistance of plant
pathogens to this agent. Briefly, this method involves serial dilutions (1:2) of the test agent in TSB, a liquid growth medium. After the dilutions were made, an aliquot of bacterial suspensions was added to each tube, except for an uninoculated
control. The tubes were incubated for 22 hours, shaking, at 27.degree. C. Three 10 .mu.L aliquots from each dilution were placed on the surface of a TSA plate, and the plates were incubated at 27.degree. C. for 96 hours.
For the first assay, as shown in FIG. 17, the test agent was diluted in ten replicates: One milliliter of Formula S-100 concentrate was added to 1 ml of the first tube of the series and mixed; 1 ml of this tube was transferred to the second tube
of 1 ml and mixed. The dilution process was repeated in subsequent tubes resulting in a final series which included the undiluted agent, 1:2, 1:4, 1:8, 1:16, 1:32, 1:64, 1:128, 1:256, 1:512, and 1:1024 dilutions.
For the second assay, as shown in FIG. 18, FIG. 19, and FIG. 20, the test agent was serially diluted as a single replicate, but in sufficient volume to dispense one-milliliter aliquots for each of the two replicates of each strain tested. This
dilution series extended from the undiluted agent out to 1:131,072, in two-fold dilutions.
For each of the assays, control tubes were included: broth only and bacteria+broth (no agent). Additional control was included for the second assay: the dilution series with no bacteria added was checked for the absence of contaminating
bacteria. Each bacterial isolate was tested in two replicate dilutions of the treatment.
The Minimum Inhibitory Concentration of an agent is the highest dilution or lowest concentration which prevents the growth of a bacterial culture. In a standard MIC assay, bacterial growth is assessed after incubation by comparing each tube of
the dilution series visually or turbidimetrically against the control tube which contains the bacterial suspension with no test agent. We modified the MIC protocol by plating triplicate 10 f.iL aliquots of each test dilution and controls on TSA II.TM.
Trypticase Soy Agar (BBL, Cockeysville, Md.) medium to validate and quantitate bacterial survival. The assay plates were incubated at 27.degree. C., examined every 24 hours, and bacterial growth was recorded for controls and each dilution 96 hours
after inoculation. The assay plates were kept for an additional 10-12 days at 27.degree. C. to determine whether there were any "escapes" or additional surviving cells.
Further, the results of independent assays are presented in table format and attached. The growth of bacteria was recorded as positive (+) or negative (-) based on visible growth in the areas of inoculum (triplicate spots) on the agar plates.
The minimum inhibitory concentration of agents is indicated on the tables by a yellow shading of cells; growth of bacteria by green shading.
The three subspecies of Clavibacter michiganensis tested had indistinguishable sensitivities to Formula S-100, not surprising given the extensively confirmed relatedness. Curtobacterium flaccumfaciens pv. flaccumfaciens was much less
sensitive, a surprising result because this pathogen is closely related to the other three.
There are limited bacterial control agents currently registered for crop protection. Screening for cost-effective bactericides including bio-based, synthetic, and inorganic compounds frequently begins in the laboratory within vitro assays to
evaluate the activity of the agent against target organisms in a non-plant system under standardized conditions. In vitro activity of an agent against a target organism, suggests potential but does not predict efficacy in plant disease control.
The assays of Formula S-100 demonstrated its in vitro activity at 22 hours against multiple isolates of four important bacterial pathogens of important crops. Even at very low concentrations, Formula S-100 was highly active against Cmn, the
causal agent of Goss's wilt and blight of maize, Cmm, the causal agent of bacterial canker of tomato and Cmi, the causal agent of bacterial wilt of alfalfa, as shown in FIG. 18 and FIG. 19. Except for one of the two strains of Cmi (which may be an
atypical strain), these pathogens did not survive at a concentration of 61 ppm (MIC=1:16384), which is impressive. Previously, Cmn was tested against S-102, and in those tests, the pathogen did not survive a concentration of 980 ppm (or 0.098%)
(MIC=1:1024).
Formula S-100 demonstrated a reduced activity at 22 hours against Cff, the agent of bacterial wilt of bean (MIC=1:64 for one isolate and MIC=1:128 for the other). These results for Cff were similar to the results for S-102 vs. Cff.
The activity of Formula S-101 at two hours was tested for one of the two replicates for two strains of Cmn, one strain of Cmm, one strain of Cmi, and the Cff strain, as shown in FIG. 20. The results at two hours, limited as the result was by
assaying only one replicate of fewer strains, were similar to the results at 22 hours, but the additional incubation time did appear to allow lower concentrations of Formula S-100 to be more effective relative to the two-hour incubation.
Based on these promising results, areas for further study might include a testing activity of Formula S-101 or S-102 (or both) at several concentrations in a greenhouse and field-grown plants to evaluate efficacy and phytotoxicity in planta (in
plants), selection of a delivery method of agent and pathogen, and time sequence studies to assess death rate of bacterial pathogens when the agent is applied prior to or after plant inoculation.
FIG. 18 is a table 1800 of a second screen of pathogens vs. dilution of Formula S-101, in accordance with some embodiments. Further, the second screen may include results at 96 hours after treatment for 22 hours.
FIG. 19 is a table 1900 of the second screen of pathogens vs. dilution of Formula S-101, in accordance with some embodiments. Further, the second screen may include results at 96 hours after treatment for 22 hours.
FIG. 20 is a table 2000 of a subset of the second screen of pathogens vs. dilutions of Formula S-101, in accordance with some embodiments. Further, the second screen of the subset may include results at 96 hours after treatment for either 2 or
22 hours.
FIG. 21 is a table 2100 of therapeutic options for fungal lung infections.
FIG. 22 is a table 2200 of antifungal treatment options.
FIG. 23 is a flow diagram of a method 2300 of facilitating producing the medicine composition for treating diseases using the medicine composition, in accordance with some embodiments. Further, the medicine composition may include the
carbanions. Further, the method 2300 may include four stages 2302-2308. Further, the four stages 2302-2308 may include a mining stage 2302, a mixture stage 2304, a production stage 2306, and a treatment stage 2308.
FIG. 24 is a flow diagram of the method 2300 of facilitating producing the medicine composition for treating the diseases using the medicine composition, in accordance with some embodiments. Further, at 2402, the mining stage 2302 may include
gathering plants. Further, at 2404, the mining stage 2302 may include extracting carbon. Further, at 2406, the mixture stage 2304 may include gathering the extracted carbon. Further, at 2408, the mixture stage 2304 may include adding additional
ingredients to the carbon. Further, at 2410, the mixture stage 2304 may include mixing until the ingredients and carbon are well combined. Further, at 2412, the production stage 2306 may include placing the mixture in a container that may be able to
sustain heat. Further, at 2414, the production stage 2306 may include applying the heat to create an exothermic reaction to the mixture. Further, at 2416, the production stage 2306 may include forming of the carbanions within the mixture. Further, at
2418, the treatment stage 2308 may include inserting one ounce of water into a nebulizer. Further, at 2420, the treatment stage 2308 may include inserting three droplets of the product comprising the carbanion into the nebulizer. Further, at 2422, the
treatment stage 2308 may include using the nebulizer and inhaling until the nebulizer is empty.
FIG. 25 is a flow diagram of the mining stage 2302 of the method 2300, in accordance with some embodiments.
FIG. 26 is a flow diagram of the mixture stage 2304 of the method 2300, in accordance with some embodiments.
FIG. 27 is a flow diagram of the production stage 2306 of the method 2300, in accordance with some embodiments.
FIG. 28 is a flow diagram of the treatment stage 2308 of the method 2300, in accordance with some embodiments.
FIG. 29 is a table 2900 of compositional elements of the medicine composition, in accordance with some embodiments.
FIG. 30 is a chart 3000 of the lab results of the medicine composition, in accordance with some embodiments.
FIG. 31 is a table 3100 of compositional elements of the medicine composition, in accordance with some embodiments.
Although the present disclosure has been explained in relation to its preferred embodiment, it is to be understood that many other possible modifications and variations can be made without departing from the spirit and scope of the disclosure.
United States Patent |
11,225,632 |
Wilshe
|
January 18, 2022
|
Cleaning composition for facilitating cleaning surfaces of an object using
femtotechnology
Abstract
Disclosed herein is a cleaning composition for facilitating cleaning
surfaces of an object, in accordance with some embodiments. Accordingly,
the cleaning composition may include carbanions and a diluting agent.
Further, a carbanion of the carbanions may include a carbon atom.
Further, the carbon atom may include a formal charge of -1. Further, the
diluting agent may be capable of combining with the carbanions for
forming at least one appliable form of the cleaning composition. Further,
a ratio of the diluting agent to the carbanions by volume may be 64:1.
Further, the combining facilitates applying of the at least one appliable
form of the cleaning composition to at least one surface of the object.
Further, the applying of the at least one appliable form of the cleaning
composition cleans at least one contaminant present on the at least one
surface of the object.
Inventors: |
Wilshe; Donald Richard (Parrish, FL) |
Applicant: | Name | City | State | Country | Type | Wilshe; Donald Richard | Parrish | FL | US |
|
|
Family ID:
|
79293901
|
Appl. No.:
|
17/349,254 |
Filed:
|
June 16, 2021 |
Related U.S. Patent Documents
| | | | | |
| Application Number | Filing Date | Patent Number | Issue Date | |
---|
| 63065232 | Aug 13, 2020 | | | |
|
Current U.S. Class: | 1/1 |
Current CPC Class: |
C11D 7/5004 (20130101); C11D 7/265 (20130101); C11D 11/04 (20130101); C11D 7/5022 (20130101); C11D 7/44 (20130101); C11D 11/0041 (20130101) |
Current International Class: |
C11D 3/48 (20060101); C11D 7/44 (20060101); C11D 11/00 (20060101); C11D 7/50 (20060101) |
Field of Search: |
;510/337
|
References Cited [Referenced By]
U.S. Patent Documents
Primary Examiner: Webb; Gregory E
Parent Case Text
The current application claims a priority to the U.S. Provisional Patent
application Ser. No. 63/065,232 filed on Aug. 13, 2020.
Claims
What is claimed is:
1. A cleaning composition for facilitating cleaning surfaces of an object, the cleaning composition comprising: carbanions, wherein a carbanion of the carbanions comprises a
carbon atom, wherein the carbon atom comprises a formal charge of -1; and a diluting agent, wherein the diluting agent is capable of combining with the carbanions for forming at least one appliable form of the cleaning composition, wherein a ratio of
the diluting agent to the carbanions by volume is 64:1, wherein the combining facilitates applying of the at least one appliable form of the cleaning composition to at least one surface of the object, wherein the applying of the at least one appliable
form of the cleaning composition cleans at least one contaminant present on the at least one surface of the object.
2. The cleaning composition of claim 1, wherein each carbanion of the carbanions is capable of creating an electromechanical reaction with at least one of an organic material and an inorganic material of the at least one contaminant present on
the at least one surface of the object based on the applying of the at least one appliable form of the cleaning composition, wherein the creating of the electromechanical reaction disassembles at least one of the organic material and the inorganic
material for cleaning the at least one surface of the object.
3. The cleaning composition of claim 2, wherein the at least one contaminant comprises at least one organism, wherein the at least one organism is present on the at least one surface of the object, wherein the at least one organism is comprised
of at least one of the organic material and the inorganic material, wherein the creating of the electromechanical reaction disassemble at least one of the organic material and the inorganic material of the at least one organism for eliminating the at
least one organism, wherein the eliminating of the at least one organism cleans the at least one surface of the object.
4. The cleaning composition of claim 3 further comprising at least one inhibiting agent for inhibiting at least one of a growth and a proliferation of the at least one organism on the at least one surface of the object based on the applying,
wherein the inhibiting facilitates the cleaning of the at least one surface of the object.
5. The cleaning composition of claim 1 further comprising at least one protective agent for forming a protective layer on the at least one surface based on the applying, wherein the forming of the protective layer prevents subsequent
contaminating of the at least one surface of the object with the at least one contaminant.
6. The cleaning composition of claim 1, wherein the carbanions are derived from at least one organic material, wherein the at least one organic material is associated with at least one part of at least one plant.
7. The cleaning composition of claim 1, wherein the carbon atom is associated with a hybridization state, wherein the hybridization state is sp3 hybridization state, wherein the carbon atom in the sp3 hybridization state is trivalent, wherein
the carbon atom in the sp3 hybridization state comprises a lone pair of electrons on the carbon atom.
8. The cleaning composition of claim 1, wherein the diluting agent comprises at least one a polar solvent and a nonpolar solvent, wherein at least one of the polar solvent and the nonpolar solvent is capable of combining with the carbanions for
forming the at least one appliable form.
9. The cleaning composition of claim 8, wherein the polar solvent comprises water, wherein the water is capable of combining with the carbanions for forming a first solution, wherein the at least one appliable form comprises the first solution,
wherein the combining facilitates applying of the first solution of the cleaning composition to at least one surface of the object.
10. The cleaning composition of claim 8, wherein the polar solvent comprises at least one organic acid, wherein the at least one organic acid is capable of combining with the carbanions for forming a second solution, wherein the at least one
appliable form comprises the second solution, wherein the combining facilitates applying of the second solution of the cleaning composition to at least one surface of the object.
11. A method for producing a cleaning composition to facilitate cleaning surfaces of an object, the method comprising: extracting at least one organic material from at least one organic material source, wherein the at least one organic material
comprises carbon atoms; blending the at least one organic material with at least one reagent for forming a composition preform; applying at least one of a specific temperature and a specific pressure to the composition preform, wherein the applying
initiates a chemical reaction in the composition preform, wherein the chemical reaction comprises at least one of a redox reaction and a reduction reaction, wherein the carbon atoms are reduced to form carbanions based on the at least one of the redox
reaction and the reduction reaction, wherein a carbon atom of the carbanions comprises a formal charge of -1; and combining the carbanions with a diluting agent for forming at least one appliable form of the cleaning composition, wherein a ratio of the
diluting agent to the carbanions by volume is 64:1, wherein the combining facilitates applying of the at least one appliable form of the cleaning composition to at least one surface of the object, wherein the applying of the at least one appliable form
of the cleaning composition cleans at least one contaminant present on the at least one surface of the object.
12. The cleaning composition of claim 11, wherein each carbanion of the carbanions is capable of creating an electromechanical reaction with at least one of an organic material and an inorganic material of the at least one contaminant present
on the at least one surface of the object based on the applying of the at least one appliable form of the cleaning composition, wherein the creating of the electromechanical reaction disassembles at least one of the organic material and the inorganic
material for cleaning the at least one surface of the object.
13. The cleaning composition of claim 12, wherein the at least one contaminant comprises at least one organism, wherein the at least one organism is present on the at least one surface of the object, wherein the at least one organism is
comprised of at least one of the organic material and the inorganic material, wherein the creating of the electromechanical reaction disassemble at least one of the organic material and the inorganic material of the at least one organism for eliminating
the at least one organism, wherein the eliminating of the at least one organism cleans of the at least one surface of the object.
14. The cleaning composition of claim 13 further comprising adding at least one inhibiting agent to the carbanions, wherein the combining of the carbanions with the diluting agent is further based on the adding of the at least one inhibiting
agent, wherein the at least one inhibiting agent inhibits at least one of a growth and a proliferation of the at least one organism on the at least one surface of the object based on the applying, wherein inhibiting facilitates the cleaning of the at
least one surface of the object.
15. The cleaning composition of claim 11 further comprising adding at least one protective agent to the carbanions, wherein the combining of the carbanions with the diluting agent is further based on the adding of the at least one protective
agent, wherein the at least one protective agent forms a protective layer on the at least one surface based on the applying, wherein forming of the protective layer prevents subsequent contaminating of the at least one surface of the object with the at
least one contaminant.
16. The cleaning composition of claim 11, wherein the carbanions are derived from at least one organic material, wherein the at least one organic material is associated with at least one part of at least one plant.
17. The cleaning composition of claim 11, wherein the carbon atom is associated with a hybridization state, wherein the hybridization state is sp3 hybridization state, wherein the carbon atom in the sp3 hybridization state is trivalent, wherein
the carbon atom in the sp3 hybridization state comprises a lone pair of electrons on the carbon atom.
18. The cleaning composition of claim 11, wherein the diluting agent comprises at least one a polar solvent and a nonpolar solvent, wherein at least one of the polar solvent and the nonpolar solvent is capable of combining with the carbanions
for forming the at least one appliable form.
19. The cleaning composition of claim 18, wherein the polar solvent comprises water, wherein the water is capable of combining with the carbanions for forming a first solution, wherein the at least one appliable form comprises the first
solution, wherein the combining facilitates applying of the first solution of the cleaning composition to at least one surface of the object.
20. The cleaning composition of claim 18, wherein the polar solvent comprises at least one organic acid, wherein the at least one organic acid is capable of combining with the carbanions for forming a second solution, wherein the at least one
appliable form comprises the second solution, wherein the combining facilitates applying of the second solution of the cleaning composition to at least one surface of the object.
Description
FIELD OF THE
INVENTION
Generally, the present disclosure relates to the field of cleaning compositions for solid surfaces, auxiliary compositions therefor, or processes of preparing the compositions. More specifically, the present disclosure relates to a cleaning
composition for facilitating cleaning surfaces of an object using femtotechnology.
BACKGROUND OF THE INVENTION
Existing compositions for facilitating cleaning surfaces of an object are deficient with regard to several aspects. For instance, existing compositions do not include carbanions. Furthermore, current compositions do not include plant-derived
carbanions.
Therefore, there is a need for a cleaning composition for facilitating cleaning surfaces of an object using femtotechnology that may overcome one or more of the above-mentioned problems and/or limitations.
SUMMARY OF THE INVENTION
This summary is provided to introduce a selection of concepts in a simplified form, that are further described below in the Detailed Description. This summary is not intended to identify key features or essential features of the claimed subject
matter. Nor is this summary intended to be used to limit the claimed subject matter's scope.
Disclosed herein is a cleaning composition for facilitating cleaning surfaces of an object using femtotechnology, in accordance with some embodiments. Accordingly, the cleaning composition may include carbanions and a diluting agent. Further,
a carbanion of the carbanions may include a carbon atom. Further, the carbon atom may include a formal charge of -1. Further, the diluting agent may be capable of combining with the carbanions for forming at least one appliable form of the cleaning
composition. Further, a ratio of the diluting agent to the carbanions by volume may be 64:1. Further, the combining facilitates applying of the at least one appliable form of the cleaning composition to at least one surface of the object. Further, the
applying of the at least one appliable form of the cleaning composition cleans at least one contaminant present on the at least one surface of the object.
Further disclosed herein is a method for producing a cleaning composition to facilitate cleaning surfaces of an object, in accordance with some embodiments. Accordingly, the method may include a step of extracting at least one organic material
from at least one organic material source. Further, the at least one organic material may include carbon atoms. Further, the at least one organic material may include a carbon compound. Further, the method may include a step of blending the at least
one organic material with at least one reagent for forming a composition preform. Further, the method may include a step of applying at least one of a specific temperature and a specific pressure to the composition preform. Further, the applying
initiates a chemical reaction in the composition preform. Further, the chemical reaction may include at least one of a redox reaction and a reduction reaction. Further, the carbon atoms may be reduced to form carbanions based on the at least one of the
redox reaction and the reduction reaction. Further, a carbon atom of the carbanions may include a formal charge of -1. Further, the method may include a step of combining the carbanions with a diluting agent for forming at least one appliable form of
the cleaning composition. Further, a ratio of the diluting agent to the carbanions by volume may be 64:1. Further, the combining facilitates applying of the at least one appliable form of the cleaning composition to at least one surface of the object.
Further, the applying of the at least one appliable form of the cleaning composition cleans at least one contaminant present on the at least one surface of the object.
Both the foregoing summary and the following detailed description provide examples and are explanatory only. Accordingly, the foregoing summary and the following detailed description should not be considered to be restrictive. Further,
features or variations may be provided in addition to those set forth herein. For example, embodiments may be directed to various feature combinations and sub-combinations described in the detailed description.
BRIEF DESCRIPTION OF THE DRAWINGS
The accompanying drawings, which are incorporated in and constitute a part of this disclosure, illustrate various embodiments of the present disclosure. The drawings contain representations of various trademarks and copyrights owned by the
Applicants. In addition, the drawings may contain other marks owned by third parties and are being used for illustrative purposes only. All rights to various trademarks and copyrights represented herein, except those belonging to their respective
owners, are vested in and the property of the applicants. The applicants retain and reserve all rights in their trademarks and copyrights included herein, and grant permission to reproduce the material only in connection with reproduction of the granted
patent and for no other purpose.
Furthermore, the drawings may contain text or captions that may explain certain embodiments of the present disclosure. This text is included for illustrative, non-limiting, explanatory purposes of certain embodiments detailed in the present
disclosure.
FIG. 1 is a table listing ingredients of cleaning composition for facilitating cleaning surfaces of an object using femtotechnology, in accordance with some embodiments.
FIG. 2 is a flowchart of a method for producing a cleaning composition to facilitate cleaning surfaces of an object, in accordance with some embodiments.
FIG. 3 illustrates carbanions of the cleaning composition for facilitating cleaning surfaces of the object, in accordance with some embodiments.
FIG. 4 is a flowchart of a process for producing the carbanions of the cleaning composition for facilitating cleaning of the object, in accordance with some embodiments.
FIG. 5 is a flowchart of a process for producing a solution of the cleaning composition, in accordance with some embodiments.
FIG. 6 is a flowchart of a process for facilitating cleaning of the object using the cleaning composition, in accordance with some embodiments.
FIG. 7 is a schematic of a carbanion of the carbanions, in accordance with some embodiments.
DETAIL DESCRIPTIONS OF THE INVENTION
As a preliminary matter, it will readily be understood by one having ordinary skill in the relevant art that the present disclosure has broad utility and application. As should be understood, any embodiment may incorporate only one or a
plurality of the above-disclosed aspects of the disclosure and may further incorporate only one or a plurality of the above-disclosed features. Furthermore, any embodiment discussed and identified as being "preferred" is considered to be part of a best
mode contemplated for carrying out the embodiments of the present disclosure. Other embodiments also may be discussed for additional illustrative purposes in providing a full and enabling disclosure. Moreover, many embodiments, such as adaptations,
variations, modifications, and equivalent arrangements, will be implicitly disclosed by the embodiments described herein and fall within the scope of the present disclosure.
Accordingly, while embodiments are described herein in detail in relation to one or more embodiments, it is to be understood that this disclosure is illustrative and exemplary of the present disclosure, and are made merely for the purposes of
providing a full and enabling disclosure. The detailed disclosure herein of one or more embodiments is not intended, nor is to be construed, to limit the scope of patent protection afforded in any claim of a patent issuing here from, which scope is to
be defined by the claims and the equivalents thereof. It is not intended that the scope of patent protection be defined by reading into any claim limitation found herein and/or issuing here from that does not explicitly appear in the claim itself.
Thus, for example, any sequence(s) and/or temporal order of steps of various processes or methods that are described herein are illustrative and not restrictive. Accordingly, it should be understood that, although steps of various processes or
methods may be shown and described as being in a sequence or temporal order, the steps of any such processes or methods are not limited to being carried out in any particular sequence or order, absent an indication otherwise. Indeed, the steps in such
processes or methods generally may be carried out in various different sequences and orders while still falling within the scope of the present disclosure. Accordingly, it is intended that the scope of patent protection is to be defined by the issued
claim(s) rather than the description set forth herein.
Additionally, it is important to note that each term used herein refers to that which an ordinary artisan would understand such term to mean based on the contextual use of such term herein. To the extent that the meaning of a term used
herein--as understood by the ordinary artisan based on the contextual use of such term--differs in any way from any particular dictionary definition of such term, it is intended that the meaning of the term as understood by the ordinary artisan should
prevail.
Furthermore, it is important to note that, as used herein, "a" and "an" each generally denotes "at least one," but does not exclude a plurality unless the contextual use dictates otherwise. When used herein to join a list of items, "or" denotes
"at least one of the items," but does not exclude a plurality of items of the list. Finally, when used herein to join a list of items, "and" denotes "all of the items of the list."
The following detailed description refers to the accompanying drawings. Wherever possible, the same reference numbers are used in the drawings and the following description to refer to the same or similar elements. While many embodiments of
the disclosure may be described, modifications, adaptations, and other implementations are possible. For example, substitutions, additions, or modifications may be made to the elements illustrated in the drawings, and the methods described herein may be
modified by substituting, reordering, or adding stages to the disclosed methods. Accordingly, the following detailed description does not limit the disclosure. Instead, the proper scope of the disclosure is defined by the claims found herein and/or
issuing here from. The present disclosure contains headers. It should be understood that these headers are used as references and are not to be construed as limiting upon the subjected matter disclosed under the header.
The present disclosure includes many aspects and features. Moreover, while many aspects and features relate to, and are described in the context of a cleaning composition for facilitating cleaning surfaces of an object using femtotechnology,
embodiments of the present disclosure are not limited to use only in this context.
Overview:
The present disclosure describes a cleaning composition for facilitating cleaning surfaces of an object using femtotechnology. Further, the cleaning composition may include carbanions. Further, the carbanions may include negatively charged
carbon atoms. Further, the negatively charged carbon atoms may be created by making use of the physical chemistry of the carbanions. Further, the physical chemistry may be the study of macroscopic, atomic, subatomic, and particulate phenomena in
chemical systems in terms of the principles, practices, and concepts of physics such as motion, energy, force, time, thermodynamics, quantum chemistry, statistical mechanics, analytical dynamics and chemical equilibrium.
Physical chemistry is the study of how matter behaves on a molecular and atomic level and how chemical reactions occur. Based on the analyses, physical chemists may develop new theories, such as how complex structures are formed. Physical
chemists often work closely with materials scientists to research and develop potential uses for new materials.
Further, the physical chemistry may be used in observing the assembly of molecules and determining, measuring, and quantifying the assembly of the molecules. Further, the physical chemistry may allow for assembling of molecules in crystals and
solutions and observing and measuring of the arrangements of atoms and molecules and aggregates of the atoms and the molecules in the solutions as well as in crystals and various properties the aggregates of surfactants impart to a product. Further,
diffraction, infrared, and microscopy methods are used for observing the assembly of the molecules and determining, measuring, and quantify the assembly of the molecules. Further, the physical chemistry may be used for developing better ways to measure
and quantitate aspects of the ingredients for developing better products.
Physical chemistry provides an understanding of the physical properties of atoms and molecules, the way chemical reactions work, and what these properties reveal. Further, the physical chemistry involves analyzing materials, developing methods
to test and characterize the properties of materials, developing theories about these properties, and discovering the potential use of the materials. Using sophisticated instrumentation and equipment has always been an important aspect of physical
chemistry. Most physical chemistry labs are full of analytical instruments, which may include lasers, mass spectrometers, nuclear magnetic resonance, and electron microscopes.
Physical chemistry may provide an understanding of chemical properties and describes the behavior of chemicals using theories of physics and mathematical computations. Further, the properties and reactions of the chemicals may be predicted
using the physical chemistry.
Physical chemistry provides fundamental physical characteristics of material be it solid, liquid, or gas.
Further, the physical chemistry may be used for the development of materials, including plastics, ceramics, catalysis, electronics, fuel, batteries, surfactants and colloids, and personal care products.
Further, the carbanions may be created using Femtotechnology. Further, Femtotechnology may be described as involving the alteration of the structure and the chemical properties of individual atoms through the manipulation of energy states of
electrons within the individual atoms to produce states with unusual properties, producing some form of exotic atoms. Further, the Femtotechnology may be used in the fabrication of structures where atoms and devices may be positioned with sub-nanometer
accuracy. This may be important where interaction with a single atom or molecule may be desired.
Further, the carbanions may individual atoms or atoms in covalent bonds. Further, the individual atoms alone or the atoms in the covalent bonds may create powerful electromechanical reactions to disassemble organic material, one atom per atom
at a time. Further, the individual atoms alone or the atoms in the covalent bond may work on the fungi, the bacteria, or the viruses to eliminate the fungi, the bacteria, or the viruses. Further, the individual atoms alone or the atoms in the covalent
bond may eliminate Shingles, Basil Cell Cancer, Squamous Cell Cancer, Poison Ivy, Oak, Sumac, Diabetic Ulcers, Wounds, Plaque Psoriasis, Genetic Blistering, Head lice, and Whopping Cough of humans. Further, the individual atoms alone or the atoms in the
covalent bond may regenerate or grow the skins on the humans.
Further, the carbanions may attack pests at the atom level. Further, at the atom level, the shield of the pests starts to disassemble eliminating the shield and killing the pests.
Further, the Femtotechnology may be used for altering electron distributions around atoms to promote surface energy to achieve inhibited infection without potential nanomaterial toxicity concerns. Further, the Femtotechnology may be used to
describe the control of electron distribution around the atoms to provide desirable properties. Further, the control of the electron distribution may greatly change surface energy and, thus, the way that proteins adsorb onto a material. Further, the
excitement or rearrangement of electrons around the atoms may influence many cellular functions including cell movement, intracellular transport to organelles, adhesion, growth, and ECM formation.
Further, the Femtotechnology may be used for altering electron distributions around atoms to promote surface energy to achieve similar increased tissue growth, decreased inflammation, and inhibited infection without potential nanomaterial
toxicity concerns. A potentially less toxic method that is used to increase tissue growth and create the next generation of tissue engineering materials is to use Femtotechnology. Further, Femtotechnology may be used to control the electron
distribution around atoms, so as to provide desirable properties. Having control over electron distribution may greatly change surface energy and, thus, the way that proteins adsorb onto a material. Therefore, through the excitement or rearrangement of
electrons around atoms, one has the ability to influence many cellular functions including cell movement, intracellular transport to organelles, adhesion, growth, and ECM formation.
Further, the Femtotechnology may control cellular microtubules (MTs). MTs s are cylindrical cellular formations 25 nm in diameter, and they are made out of tubulins. Dynamic instability due to MT plus end-binding proteins also called "plus
end-tracking proteins", are able to "surf" the dynamic ends of MTs. Further, when tips are expressed as green fluorescent proteins, the fluorescence is the brightest at the MT and decreases in intensity toward the minus end of the MT, forming a comet
tail. Further, external stimulation is used to excite the MT and end-binding proteins to promote the movement of cells using the Femtotechnology. This may be a less toxic manner through which to alter surface energy to increase tissue growth since
electron distributions may be changed for numerous macro-, micro-, or nanomaterials. Further, the Femtotechnology may be used to reduce the toxicity in any macro-, micro-, or nanomaterials by exciting electrons. The change in electron distribution,
along with the associated charge redistribution, may alter surface energetics to change the adsorption of certain proteins (as well as cellular functions).
Further, the carbanions may include carbon atoms. Further, the carbon atoms may be associated with CO2 (carbon dioxide) gas. Further, an average person breathes out around 500 liters of the greenhouse gas CO2, which amounts to around 1 kg or
2.3 pounds of mass. Further, the world's population is around 6.8 billion, collectively breathing out around 2500 million tons of CO2, which is around 7 percent of the annual CO2 tonnage churned out by the burning of fossil fuel around the world.
Further, the CO2 breath out by the average person may be a part of a natural cycle, by which the body of the average person may convert carbohydrates from CO2-absorbing plants into energy, plus water and CO2. Further, the carbanions may include a
Pico-19 product. Further, the Pico-19 product may be made of carbon atoms from CO2. Further, the average person may breathe the carbon atoms of the CO2 and consume the carbon atoms of vegetables of plants. Further, the body of the average person may
include 50% carbon as the average person consumes the plant.
Further, electrons are used to make the carbon atoms of the carbanions negatively charged and the carbanions do not have a no-charge carbon atom. That makes the carbanions a 10 to 15th cleaner. Further, the carbanions applications are for
water, soils, and molecule to atom product or a molecule splitter.
Further, the carbanions may be used to make femto-products. Further, the femto-products may include a "FemtoMed". Further, the "FemtoMed" may control Bacteria, Insects, Fungi, and viruses. Further, the "FemtoMed" may be created using Pico
technology.
Further, the "FemtoMed" pesticide qualifies as a Biopesticide, Biostimulant, Biofertilizer, and Biologicals.
Further, the "FemtoMed" may be used for the elimination of vital elements in Bacteria, Insects, Fungi, and viruses.
Further, the "FemtoMed" is configured for eliminating the cell membrane of the bacteria and puncturing the cell membrane. Further, the eliminating and the puncturing of the cell membrane may drain proteins and lipids from the bacteria.
Further, the "FemtoMed" is configured for eliminating the cellulose and chitin of the fungus.
Further, the "FemtoMed" is configured for eliminating strands of a nucleic acid of the virus, either DNA or RNA of the virus, and protective protein coat of the virus (the capsid), or a lipid envelope of the virus, surrounding the protein of the
virus.
Further, the "FemtoMed" is configured for eliminating or penetrating and dissolve lipid cellular membranes of the insects, cells desiccation of the insects, cellular metabolism of the insects, dissolving cuticles of the insects, lubrication
joints of the insects leading to paralysis, stripping the pests protective shields of the insects, exoskeleton structure of the insects, chitin and protein substances of the insects, hydrocarbon chains smothering of the insects.
Further, the "FemtoMed" immediately impacts the exoskeleton structure of the pest upon contact by disrupting the molecular structure of the chitin and other protein substances that protect the insect. This mechanism of action triggers the rapid
and irreversible deterioration of the insect's spiracles and tracheal system, resulting in suffocation. Further, the "FemtoMed" kills insects with the elimination of chitin. Further, chitin is a polysaccharide and a carbohydrate that has a chain of
sugar molecules. Further, chitin has a structure like cellulose. Additionally, the chitin may be present in the exoskeletons of the insects.
Further, the "FemtoMed" benefit from the revolutionary method of insect control with an absence of undesirable side effects on human health and no harm to the ecosystem. Additionally, unlike standard insecticides in use today, no built-in
resistance may be developed by the targeted insects, but rather on the respirators apparatus.
Further, the "FemtoMed" may be mechanical in primary sequential steps. Further, a first step is a direct interaction between the surface and the outer membrane of the pests, causing the membrane to rupture and leak fluids, proteins, and
nutrients.
Lastly, in a few more ways, the "FemtoMed" electromechanical may affect the pests: There may be a second step related to the holes in the outer membrane, through which the pests lose vital nutrients, protein, water, and components, causing a
general weakening of the pests. Electromechanical may affect pests by penetration and dissolving of lipid cellular membranes. This causes cell desiccation to leak water, proteins, and nutrients and collapse. By interfering with cellular metabolism
during metamorphosis. By dissolving cuticles, the lubrication in the insect and joints of the insects leading to paralysis. By stripping the pests' protective shields (wax, biofilm, etc), rendering the pests defenseless against subsequent treatment.
The extracts impact the exoskeleton structure of the pests upon contact by disrupting the molecular structure of the chitin and other protein substances that protect the insect. The extracts may have the ability to penetrate complex hydrocarbon chains
and disintegrate the insects. The extracts may emulsify the pests thus stopping the reproduction cycle. The change in the environment for growth with PH from acidophils and neutrophils to alkaliphiles.
Further, the "FemtoMed" may be configured for punching holes in a cell of the pests. Further, the punching holes in the cell breaching the cell's main defense. Further, an unopposed stream of the "FemtoMed" enters the cell. This puts several
vital processes inside the cell in danger. Further, the "FemtoMed" overwhelms the inside of the cell and obstructs cell metabolism (i.e., the biochemical reactions needed for life) Further, the "FemtoMed" binds to enzymes of the cell halting the activity
of the cell. Further, the pests no longer "breathe", "eat", "digest", "reproduce" or "exist".
Further, an outer membrane of the cell, including that of a single cell organism like pests, is characterized by a stable electrical micro-current. This is often called "transmembrane potential", and is literally, a voltage difference between
the inside and the outside of a cell It is strongly suspected that when a pest comes in contact with the "FemtoMed", short-circuiting of the current in the cell membrane may occur. Further, the current weakens the outer membrane and creates holes, and
leak water, proteins, and nutrients from the cell.
Further, the "FemtoMed" effect fast, and affects such a wide range of pests.
The experiences observed explain the speed with which pests and other pests perish on "FemtoMed" surfaces by the multi-targeted effects. After membrane perforation, may inhibit any given enzyme that "stands in its way," and stop the ceil from
transporting or digesting nutrients, from repairing its damaged membrane, from breathing or multiplying Harmless to Environment Air, Water, Soil, Humans, Birds, and Animals This has no side effects or harm on human, birds and animal health. These
solutions do not harm mammal cells nor the solutions attack the neurological systems of humans, birds, and animals. Further, the "FemtoMed" may lyse cells to extract protein or organelles, or to permeabilize the membranes of living cells.
The organic product dissolves lipids from cell membranes making the cell membranes permeable to antibodies. Because the organic solvents also coagulate proteins, the organic product may be used to fix and permeabilize cells at the same time.
Saponin interacts with membrane cholesterol, selectively removing it and leaving holes in the membrane. Permeabilization is the process of making something, such as a membrane or cell wall, permeable. Lyse is a verb referring to the process of lysis,
the death of a cell. Lysis refers to the breaking down of the membrane of a cell, often by viral, enzymic, or osmotic mechanisms that compromise cell integrity. A fluid containing the contents of lysed cells is called a lysate. In molecular biology,
biochemistry, and cell biology laboratories, cell cultures may be subjected to lysis in the process of purifying the components, as in protein purification, DNA extraction, RNA extraction, or purifying organelles.
Trophobiosis Cycle: Pests shun healthy plants Pesticides weaken plants. Weakened plants open the door to pests and disease. Further, the pesticides precipitate pest attack and disease susceptibility, and thus the pesticides induce a cycle of
further pesticide use.
Further, the carbanions may be created using Femto-technology. Further, the Femto-technology may be used for creating carbanion of the 8-octet, 9-nonet, 10-dectet, 11-undectet, and 12-duodectet by electrons addition. Further, the
Femto-technology may be used for matter manipulation for modifying a carbon atom of the carbanions.
Further, the present disclosure describes a composition comprising carbanions. Further, the carbanions are created using picotechnology and/or femtotechnology. Further, the picotechnology and/or femtotechnology works atom to atom for
mechanical disassembly of viruses, Bacteria, Insects, and Fungi control. Further, a single drop of the composition may include 5 sextillion negatively charged carbon atoms. Further, the negatively charged carbon atoms restrict viruses' elemental mode
of action by eliminating strands of nucleic acid, either DNA or RNA, and a protective protein coat (the capsid), or a lipid envelope, surrounding the protein of the viruses.
Further, the carbon atom may be manipulated using temperature or pressure for modifying the carbon atom to make a carbanion. Electron addition can be 8-octet, 9-nonet, 10-dectet, 11-undectet, and 12-duodectet.
Further, the carbon atom is a lethal killer of bacteria, fungi, viruses, or small insects.
Further, the Femtotechnology may allow using of atoms singularly. Further, the carbanions may be formed by collecting 1 to 3 atoms of the periodic table. Further, 1 to 3 atoms may be bonded together to eliminate the fungi, the bacteria, or the
viruses.
Further, femto-products comprising the carbanions may have the following characteristics:
1). No harm to air (no GWC, ODC, VOHAP, or VOC) soils or waters.
2). Can not be made of organic chemistry, graphene, or nanotechnology, just single atom Picotechnology or physical chemistry
3). Goals are primary distribution as an OTC product.
4). It must be made of atomic elements and not molecules.
5). Must be able to kill all pests, be it bacteria, fungi, viruses, and insects.
6). Must be able to deep clean and grow skin and heal wounds just days not weeks
7). Must be able to penetrate the shields of all pests.
8). Must be approved at the State and or Federal FDA or better be exempt.
9). Must be safe for humans, bees, birds, and animals--zero side effects.
10). Must be made of 100% new organic carbon.
11). No Chemicals
12). No Biologicals
13). No Nanotechnology
14). No Graphene
15). No Molecules
16). Eliminate Sickness
Further, the femto-products facilitate Soil and Ground Water Remediation. Further, the femto-products may form Physical Chemistry At 600 Picometers or 2 Atoms Size. Further, the femto-products may 89% Biobased Content. Further, the femto-products
may include ingredients such as EAFUS: A Food Additives. Further, the femto-products may not include hazardous Canadian Heavy 11 Metal. Further, the femto-products particle size provides trans-location and remediation. Further, the femto-products may
restructure water, and spray rig pressure drops by 19%. Further, the femto-products may increase Brix levels from 100% to 200%. Further, the femto-products may provide Electrical Conductivity (EC) (Microsiemens). Further, the femto-products may increase
carbon dioxide consumption. Further, the femto-products may increases ERGS by 2000%. Further, the femto-products may increase Corn, Soybeans, Wheat, Oats Alfalfa production. Further, the femto-products may provide a spray rig cleaning benefit. Further,
the femto-products may provide wind resistance benefits. Further, the femto-products may provide late planting benefits. Further, the femto-products may provide frost resistance. Further, the femto-products may increases 269% Brix in macadamia benefit.
Further, the femto-products may stimulate crop production factors. Further, the femto-products don't affect good bacteria. Further, the femto-products may achieve "increasing carbon dioxide consumption". Further, the femto-products may be used as seed
wash, germ test 85% untreated to 98% treated. Further, the femto-products may provide tank mixing, water restructuring, lower dynes from 70 to 30. Further, the femto-products may be used for both organic fertilizer & organic pesticides. Further, the
femto-products may not pose any health hazards signage to workers, customers, or owners. Further, the femto-products may not require the posting of warnings signs anymore posted to protect customers or workers when spraying or applying the femto-product.
Further, the femto-products may not pose any concerns about toxic chemical sprays drifting into neighborhoods or runoff into water or air supply. Further, the femto-products may not pose any concerns over issues associated with registered pesticides when
spraying. Further, the femto-products may not require a protected storage area or special handling of dangerous chemicals. Further, the femto-products may not require any special handling, transportation, or equipment. Further, the femto-products may not
pose any threat or concern over fees and fines levied by OSHA guidelines. Further, the femto-products may not pose any threats of violating "toxic chemical libel laws" for applying more or the wrong pesticide than direct by poisonous product
instructions. Further, the femto-products may not require any hazardous waste disposal requirements to follow. Further, the femto-products may not invite workmen's compensation claims or lawsuits from customers or workers claiming insecticide exposure.
Further, the femto-products may not invite workers' compensation fees charged after receiving a waiver for reducing or eliminating pesticides and toxic cleaners. Further, the femto-products may not provide any liability for pollution mitigated for land
sales, no cleanup of pesticides. Further, the femto-products may not require closing because of spraying as now you have a zero re-entry time product. Further, the femto-products may not require any additional labor or costs required for associated
spraying and handling. Further, the femto-products may provide a "poison-free" working environment by replacing dangerous fungicides and insecticides, in multiple forms, plus degreaser, toxic detergents, numerous cleaners, and solvents. Further, the
femto-products may be self-cleans equipment applicators and reduces equipment maintenance costs. Further, the femto-products may reduce pesticide and chemical costs by up to 75%. Further, the femto-products may enhance plant root growth and nourishment by
breaking the surface tension of water for deeper and more rapid soil penetration. Further, the femto-products may increases product yields from 105% to 300%. Further, the femto-products may appear to strengthen the plant, which provides stronger blooms
and increases systemic acquired resistance, defending plants from insects and fungus. Further, the femto-products may increase plant growth by 10% to 300% over a 3-month period of time for starter plants. Further, the femto-products may save $3,000 to
$5,000 annually by reducing discarded plants on a nursery. Further, the femto-products may be a non-toxic product that can be recommended and sold to customers and other growers. Further, the femto-products provide increased peace of mind about crop
success and non-poisonous operations at reduced costs. Further, the femto-products may facilitate faster crop production more turnover of crops in fields and greenhouses. Further, the femto-products may facilitate a 15% increase in greenhouses and
possibly a 100% increase in annual field production by growing an extra crop per annum. Further, faster crops mean less borrowing costs on crop loans. Further, the femto-products may be alternated, rotated, or mixed with chemicals to lower costs and
reduce environmental pollution and worker safety. Further, the femto-products may be used for washing hands, cleaning tools therefore not spreading diseases from plant to plant or tree to tree or human to customer. Further, 120-day rice crops grown in
100 days with up to 45% yield increase, 120-day onion crop grown in 90 days with 30% more products based on an application of the femto-products. Further, the femto-products may increase the quality of grains and nutrients of crops grown. Further, the
femto-products may decrease the plum harvest rejection rate from 65% to only 35%. Further, the quality of fruit and skin now meets the shipping standards. Further, the femto-products may is made from 100% US GOV food and drug administration (FDA) EAFUS
food additives. Further, the femto-products may is defined as food by the FDA. Further, the femto-products may improve the plant's electro-mechanical function, which enables cells to communicate more efficiently and be more productive. Further, the
femto-products that may increase plant Brix/sugar levels by up to 100% have been recorded. Further, the femto-products may be used to supply nutrients to seeds that encourage germination and vigorous growth. Further, plants sprayed with the pic-product
reduce co2 from the atmosphere by up to 33% by increasing plant sugar levels in the photosynthesis process. Further, the femto-products may produce potential benefits such as claimed carbon credits that help to reduce the price of femto-products.
Further, the femto-products may be nontoxic, non-hazardous, cost-effective, and humanly safe. Further, the femto-products may reduce hunger, starvation, and poverty with increased production.
Further, a femto-product may facilitate skin clearing and cure psoriasis. Further, the femto-product may heal painful lesions. Further, the femto-product may heal lesions, lumps, and specks. Further, the femto-product may decrease skin infections
decreased. Further, the femto-product may reduce black specs to surface and lesions. Further, the femto-product may lessen the sub-dermal skin movement. Further, the femto-product may lessen itching, pricking on toes, hands, fingers, skin. Further, the
femto-product reduces crawling and itching, moisturizes skin, and heals sores. Further, the femto-product reduces sting and itching. Further, the femto-product removes pimples on the chin. Further, the femto-product is a great household cleaner for
everything Further, the femto-product is used for lesions, mouth gargle, white specs, grains. Further, the femto-product stops glass itching, biting. Further, the femto-product provides smooth skin, erases wrinkles, and provides sub-dermal extraction.
Further, the femto-product reduces itching and biting. Further, the femto-product provides silky soft skin. Further, the femto-product is used as makeup. Further, the femto-product reduces welt type sores suffering and itching. Further, the femto-product
reduces crawling and biting. Further, the femto-product helps get rid of a cold and improve lung functioning. Further, the femto-product generates fibers from the body. Further, the femto-product dislodges sub-dermal foreign non-organism materials.
Further, the femto-product provides fiber extrusion and stops itching. Further, the femto-product reduces Lyme's disease, candida, and hypothyroidism. Further, the femto-product reduces lesions and provides skin softening. Further, the femto-product
provides lesion management. Further, the femto-product reduces chronic lesions. Further, the femto-product reduces lesions, healing, itching, and acne-like cysts. Further, the femto-product sloughs off dead skin. Further, the femto-product may normalize
diabetic skin on the legs and prevent amputations. Further, the femto-product reduces crawling or stinging. Further, the femto-product helps with Lyme's, fibromyalgia, molds, and fungal. Further, the femto-product fades red scars, removes fibers, and
provides smooth skin and normal skin. Further, the femto-product helps with deworming. Further, the femto-product heals painful lesions, provides deep sub-dermal extraction, and reduces skin cancer. Further, the femto-product moisturizes the skin.
Further, the femto-product removes critters on the face. Further, the femto-product helps with pricking and eyes. Further, the femto-product may be used for brushing teeth and breathing fresh. Further, the femto-product heals the foot. Further, the
femto-product provides foot care and removes discoloration and scars. Further, the femto-product reduces dandruff, shards of dead white skin, itch flakes, and bleeding, Further, the femto-product reduces eczema. Further, the femto-product helps with
psoriasis, alligator skin, scabs, and nail fungus. Further, the femto-product provides hair conditioning. Further, the femto-product reduces candida and fibroid-like lumps in the flesh. Further, the femto-product eliminates organism shedding black
particles and an itchy patch. Further, the femto-product provides bath soaking for organism shedding, organism release, itchy biting, black particles, itchy patch, parasites, and bacterial infections. Further, the femto-product reduces scabbing, scar
tissue, and hard callouses. Further, the femto-product reduces groin heat rash, eczema ear canal, poison ivy, laundry stains, fungus, mildew, and center back itch. Further, the femto-product reduces scalp and eyelids clumps/fuzz balls, black fibers, and
black specs. Further, the femto-product may prevent head sores. Further, the femto-product may be used as the liquid for bath, cream for hands, feet, and head. Further, the femto-product reduces lesions. Further, the femto-product may be used for nasal
spray and enemas. Further, the femto-product may prevent Lyme disease, creepy-crawly sensations, headache, fatigue, hair loss, chest pain, and bumps/lesions scalp. Further, the femto-product calms and soothes the itch of bacteria and Lyme rash. Further,
the femto-product prevents dental infections in molar and yeast infections. Further, the femto-product heals skin lesions faster. Further, the femto-product cleans skins, deep pathogens, Further, the femto-product reveres skin tan.
Further, the femto-product may include FemtoSoap Muratic Acid Replacement, FemtoSoap Acetone Replacement, and FemtoSoap Chlorine Replacement.
Further, the femto-product may include products such as FemtoSoap Acid Cleaner, FemtoSoap Adhesive, Mastic, Caulk Remover, FemtoSoap Adult Shampoo, FemtoSoap Adult Soaps, FemtoSoap Aircraft, and Metal Cleaner, FemtoSoap Alkaline Cleaner, FemtoSoap
All-Purpose Cleaner, FemtoSoap Anti-Allergen Additive, FemtoSoap Aqueous Cleaner Concentrate, FemtoSoap Asphalt equip. cleaner, FemtoSoap Automobile/Truck/RV Cleaner, FemtoSoap Bath & Body Wash, FemtoSoap Bath & shower gels, FemtoSoap Bathroom Cleaner,
FemtoSoap Biosolvents for oil spills, FemtoSoap Carpet & Upholstery Shampoo, FemtoSoap Carpet & Upholstery Spotter, FemtoSoap Carpet Cleaner, and FemtoSoap Carpet shampoos, FemtoSoap Carpet spot removers.
Further, the femto-product may include FemtoSoap Cleaning Products such as FemtoSoap Concrete Cleaner, FemtoSoap Concrete structure cleaners, FemtoSoap Crease Trap and Drain Cleaner, FemtoSoap Dishwasher and laundry detergents, FemtoSoap Disinfectants,
FemtoSoap DustDown Dust Palliative, FemtoSoap Dustroy Anti-Allergen Spray, FemtoSoap Fabric softeners, FemtoSoap Fabric stain removers, FemtoSoap Fertilizer, FemtoSoap Filter cleaners, FemtoSoap Filter Wash, FemtoSoap Floor & Tile Cleaner, FemtoSoap Floor
cleaning products, FemtoSoap Floor Polish, FemtoSoap Floor Pre-Spot, FemtoSoap Floor Stripper, FemtoSoap Floor, Vinyl, Tile Cleaner, FemtoSoap Fruit & Vegetable Wash, FemtoSoap Glass, fiberglass polishing agents, FemtoSoap Glass, Mirror Cleaner, FemtoSoap Glue,
adhesive, paint removers, FemtoSoap Glycerin Bath Bar, FemtoSoap Graffiti Remover, FemtoSoap Grease Trap and Drain Cleaner, FemtoSoap Hand creams & lotions, FemtoSoap Hand Dishwashing Liquid, FemtoSoap Heavy Duty Hand cleaner, FemtoSoap HVAC cleaners, FemtoSoap
Industrial parts washing fluids, FemtoSoap Ink removers, FemtoSoap Kitchen & bath cleaners, FemtoSoap Kitchen Exhaust & Hood Cleaner, FemtoSoap Laundry Detergent, FemtoSoap Laundry Pre-soak, FemtoSoap Laundry Stain Remover, FemtoSoap Lip balms, FemtoSoap Liquid
Hand Cleaner, FemtoSoap Magic Pan Hand Dishwashing Liquid, FemtoSoap Marine hull & cargo hold cleaners, FemtoSoap Mastic removers, FemtoSoap Metal cleaners, FemtoSoap Mold & Mildew Cleaner, FemtoSoap Multi-Surface Cleaner, FemtoSoap Odor-Ex Cleaning Deodorizer,
FemtoSoap Odor-Ex Odor Neutralizer, FemtoSoap Oil & grease emulsifiers, FemtoSoap Oven & Grill Cleaner, FemtoSoap Premium Laundry Detergent, FemtoSoap Printing equipment cleaners, FemtoSoap Reusable carburetor and parts cleaner, FemtoSoap Shampoo for Dogs &
Cats, FemtoSoap Solvents & Cleaners, FemtoSoap Stainless Steel Cleaner, FemtoSoap Steel Bright Polish, FemtoSoap Textile and dyeing equipment cleaner, FemtoSoap Trap and drain cleaners, FemtoSoap Tub & tile cleaners, FemtoSoap Waterless hand cleaners, and
FemtoSoap Wood, leather, vinyl cleaners.
Further, the femto-product may include Animal Farm Care such as
FemtoSoap Farm Care Abrasions, FemtoSoap Farm Care Abscesses
FemtoSoap Farm Care Aural Plaque v, FemtoSoap Farm Care Bacteria
FemtoSoap Farm Care bacterial infections, FemtoSoap Farm Care Barns
FemtoSoap Farm Care Bedding, FemtoSoap Farm Care Animal Care Bio-Films Flush Cleanse, FemtoSoap Farm Care Bumps, FemtoSoap Farm Care Car Wash, FemtoSoap Farm Care Wash reproduction stalls, FemtoSoap Farm Care Wash reproducton floors, FemtoSoap Farm
Care Milking Room Cleaning Steps 1, 2 and 3, Not 4, FemtoSoap Farm Care Containers, FemtoSoap Farm Care Cracked Heel, FemtoSoap Farm Care Culicoides Hypersensitivity, FemtoSoap Farm Care Cuts, FemtoSoap Farm Care Dermantitis, FemtoSoap Farm Care Detangles,
FemtoSoap Farm Care Dew Poisoning, FemtoSoap Farm Care Diseased Tissue, FemtoSoap Farm Care Eliminates rubbing out their tails, FemtoSoap Farm Care Scratches, FemtoSoap Farm Care Farrier work clothes, FemtoSoap Farm Care Flat sarcoids, FemtoSoap Farm Care Fly
Mask, FemtoSoap Farm Care Fly Sheets, FemtoSoap Farm Care Foot Rot, FemtoSoap Farm Care Frog removal of diseased tissue, FemtoSoap Farm Care Frog Treatment, FemtoSoap Farm Care Fungal coat problems, FemtoSoap Farm Care fungal infections v, FemtoSoap Farm Care
Fungus, FemtoSoap Farm Care Girth Rash, FemtoSoap Farm Care Grease Heel, FemtoSoap Farm Care Greasy Heel, FemtoSoap Farm Care Grooming Brushes, FemtoSoap Farm Care Hair growth promotion, FemtoSoap Farm Care Hair Wash Care, FemtoSoap Farm Care Horse Blankets,
FemtoSoap Farm Care Horse Urine, FemtoSoap Farm Care Hotspots, FemtoSoap Farm Care Increased Hair Growth, FemtoSoap Farm Care Insect bites v, FemtoSoap Farm Care insect infestations v, FemtoSoap Farm Care Itchy Horse, FemtoSoap Farm Care Lacerations, FemtoSoap
Farm Care Lice, FemtoSoap Farm Care Lumps, FemtoSoap Farm Care Mange, FemtoSoap Farm Care Mange demodectic, FemtoSoap Farm Care Mange scarcoptic, FemtoSoap Farm Care Mange, FemtoSoap Farm Care mosquitoes gnats flies Gnats No Seem Ums, FemtoSoap Farm Care Mud
Fever, FemtoSoap Farm Care Mud Foot, FemtoSoap Farm Care Mutilating stop, FemtoSoap Farm Care Nicks, FemtoSoap Farm Care Pails, FemtoSoap Farm Care Parasites v, FemtoSoap Farm Care parasites removal v, FemtoSoap Farm Care Parasites, FemtoSoap Farm Care Penile
Fibropapilloma, FemtoSoap Farm Care Pregnant mares nursing foils and weanlings, FemtoSoap Farm Care Pruritis, FemtoSoap Farm Care Pruritis elimination, FemtoSoap Farm Care Rain Rot v, FemtoSoap Farm Care Rain Scald v, FemtoSoap Farm Care Repel biting insects,
FemtoSoap Farm Care Riding Pads, FemtoSoap Farm Care Rubbing out their tails, FemtoSoap Farm Care Sacriod flat tumors removal, FemtoSoap Farm Care Saddle Blankets, FemtoSoap Farm Care Saddle Pads, FemtoSoap Farm Care Sand bumps, FemtoSoap Farm Care Scabs and
Swelling v, FemtoSoap Farm Care Scratches, FemtoSoap Farm Care Shampoo, FemtoSoap Farm Care Shines, FemtoSoap Farm Care Skin abrasions, FemtoSoap Farm Care Skin hives, FemtoSoap Farm Care Skin scurf, FemtoSoap Farm Care Sole bruising, FemtoSoap Farm Care Sole
Callus, FemtoSoap Farm Care Sole removal of diseased tissue, FemtoSoap Farm Care Sole Treatment, FemtoSoap Farm Care Sore Healing, FemtoSoap Farm Care Stable Laundry Care For Reproduction, FemtoSoap Farm Care Stable Walls and Floor Wash, FemtoSoap Farm Care
Stable Wash, FemtoSoap Farm Care Summer Itch, FemtoSoap Farm Care Sunburn relief, FemtoSoap Farm Care Swamp Fever, FemtoSoap Farm Care Thrush, FemtoSoap Farm Care Tractor Wash, FemtoSoap Farm Care Trailer Wash, FemtoSoap Farm Care Truck Wash, FemtoSoap Farm Care
Ulcerating bumps, FemtoSoap Farm Care Warts, FemtoSoap Farm Care Washes, FemtoSoap Farm Care White line disease, FemtoSoap Farm Care wound healing, FemtoSoap Farm Care Wounds, and FemtoSoap Farm Care Yeast.
Further, the present disclosure describes the cleaning composition that may include an active element Carbanion which is 688 negatively charged. Further, the cleaning composition is used to prepare cleaning products. Further, the cleaning
composition is prepared using 700 drops or 2 ounces (oz) of carbanions per gallon of water.
FIG. 1 is a table 100 listing ingredients of cleaning composition for facilitating cleaning surfaces of an object using femtotechnology, in accordance with some embodiments. Further, the table 100 may include a column 102 and two rows 104-106.
Further, the table 100 may include two cells (column 102, row 104) and (column 102, row 106). Further, the cleaning composition may include carbanions and a diluting agent.
Further, a cell (column 102, row 104) of the table 100 may be related to the carbanions. Further, a carbanion of the carbanions may include a carbon atom. Further, the carbon atom may include a formal charge of -1.
Further, a cell (column 102, row 106) of the table 100 may be related to the diluting agent. Further, the diluting agent may be capable of combining with the carbanions for forming at least one appliable form of the cleaning composition.
Further, a ratio of the diluting agent to the carbanions by volume may be 64:1. Further, 1 gallon of the diluting agent may be combined with 2 ounces (oz) of the carbanions based on the ratio of 64:1 for forming the cleaning composition. Further, the 2
ounces of the carbanions may include 700 drops of the carbanions. Further, 1 drop may include sextillion carbanions. Further, the combining facilitates applying of the at least one appliable form of the cleaning composition to at least one surface of
the object. Further, the applying of the at least one appliable form of the cleaning composition cleans at least one contaminant present on the at least one surface of the object. Further, the at least one object may include a human body, an animal
body, an item, an article, etc. Further, in an embodiment, the diluting agent and the carbanions may be combined in a plurality of volume ratios for forming at least 200 dilutions of the cleaning composition.
Further, in an embodiment, the at least one surface may be a skin of a body part of the human body. Further, the at least one contamination may include at least one infestation on the skin. Further, the applying of the at least one appliable
form of the cleaning composition may heal the skin of the at least one infestation by removing the at least one infestation. Further, the at least one infestation may cause at least one disease.
Further, in some embodiments, each carbanion of the carbanions may be capable of creating an electromechanical reaction with at least one of an organic material and an inorganic material of the at least one contaminant present on the at least
one surface of the object based on the applying of the at least one appliable form of the cleaning composition. Further, the creating of the electromechanical reaction disassembles at least one of the organic material and the inorganic material for
cleaning the at least one surface of the object. Further, in an embodiment, the at least one contaminant may include at least one organism. Further, the at least one organism may include microorganisms, insects, pests, etc. Further, the microorganisms
may include bacteria, fungi, viruses, protozoa, etc. Further, the at least one organism may be present on the at least one surface of the object. Further, the at least one organism may be comprised of at least one of the organic material and the
inorganic material. Further, the creating of the electromechanical reaction disassemble at least one of the organic material and the inorganic material of the at least one organism for eliminating the at least one organism. Further, the eliminating of
the at least one organism cleans the at least one surface of the object. In further embodiments, the cleaning composition may include at least one inhibiting agent for inhibiting at least one of a growth and a proliferation of the at least one organism
on the at least one surface of the object based on the applying. Further, the inhibiting facilitates the cleaning of the at least one surface of the object.
In further embodiments, the cleaning composition may include at least one protective agent for forming a protective layer on the at least one surface based on the applying. Further, the forming of the protective layer prevents subsequent
contaminating of the at least one surface of the object with the at least one contaminant. Further, the at least one protective agent may include a moisturizing agent, a soothing agent, etc. Further, the moisturizing agent may include mineral oils,
organic oils, vegetable oils, animal oils, etc.
Further, in some embodiments, the carbanions may be derived from at least one organic material. Further, the at least one organic material may be associated with at least one part of at least one plant.
Further, in some embodiments, the carbon atom may be associated with a hybridization state. Further, the hybridization state may be sp3 hybridization state. Further, the carbon atom in the sp3 hybridization state may be trivalent. Further,
the carbon atom in the sp3 hybridization state may include a lone pair of electrons on the carbon atom.
Further, in some embodiments, the diluting agent may include at least one a polar solvent and a nonpolar solvent. Further, the nonpolar solvent may include alcohols, ethers, etc. Further, at least one of the polar solvent and the nonpolar
solvent may be capable of combining with the carbanions for forming the at least one appliable form. Further, in an embodiment, the polar solvent may include water. Further, the water may be capable of combining with the carbanions for forming a first
solution. Further, the at least one appliable form may include the first solution. Further, the combining facilitates applying of the first solution of the cleaning composition to at least one surface of the object. Further, in an embodiment, the
polar solvent may include at least one organic acid. Further, the at least one organic acid may include acetic acid, citric acid, etc. Further, the at least one organic acid may be capable of combining with the carbanions for forming a second solution.
Further, the at least one appliable form may include the second solution. Further, the combining facilitates applying of the second solution of the cleaning composition to at least one surface of the object.
Further, in some embodiments, the carbanion may include negatively charged carbon atoms. Further, the negatively charged carbon atoms may not be active ingredients. Further, the negatively charged carbon atoms may attract positive atoms and
release the vital fluid from at least one of fungi, bacteria, viruses, and insects causing the elimination of at least one of the fungi, the bacteria, the viruses, and the insects. Further, the at least one organism may include at least one of the
fungi, the bacteria, the viruses, and the insects. Further, the negatively charged carbon atoms may make surfaces of the pests positively charged by knocking electrons out from the surface of pests.
Further, in some embodiments, the carbanions may forms particles in the solution. Further, the particles may be associated with a particle size. Further, the particle size may be less than 1 nanometer in a straight solution. Further, in an
instance, the particle size may be 0.6 nm or 600 pm. Further, the carbanions may include micelles structures. Further, the micelles structure may include a spherical shape. Further, most micelles may be 0.6 nm in particle size hydrodynamic radius.
Further, in some embodiment, the carbanion of the carbanions may include a single negatively charged carbon atom. Further, the single negatively charged carbon atom bond to no other atoms except for another single negatively charged carbon
atom.
Further, the carbanion may include "Negative Octet Energy". Further, the carbanion may be an anion in which the carbon-atom bears a formal negative charge.
FIG. 2 is a flowchart of a method 200 for producing a cleaning composition to facilitate cleaning surfaces of an object, in accordance with some embodiments. Further, at 202, the method 200 may include a step of extracting at least one organic
material from at least one organic material source. Further, the at least one organic material source may include at least one plant. Further, the at least one organic material may be 100% biomass. Further, the at least one organic material may
include carbon atoms. Further, the carbon atoms may be organic carbon atoms.
Further, at 204, the method 200 may include a step of blending the at least one organic material with at least one reagent for forming a composition preform. Further, the at least one reagent may include a reducing agent.
Further, at 206, the method 200 may include a step of applying at least one of a specific temperature and a specific pressure to the composition preform. Further, the applying initiates a chemical reaction in the composition preform. Further,
the chemical reaction may include at least one of a redox reaction and a reduction reaction. Further, the carbon atoms may be reduced to form carbanions based on the at least one of the redox reaction and the reduction reaction. Further, a carbon atom
of the carbanions may include a formal charge of -1.
Further, at 208, the method 200 may include a step of combining the carbanions with a diluting agent for forming at least one appliable form of the cleaning composition. Further, a ratio of the diluting agent to the carbanions by volume may be
64:1. Further, the combining facilitates applying of the at least one appliable form of the cleaning composition to at least one surface of the object. Further, the applying of the at least one appliable form of the cleaning composition cleans at least
one contaminant present on the at least one surface of the object.
Further, in some embodiments, each carbanion of the carbanions may be capable of creating an electromechanical reaction with at least one of an organic material and an inorganic material of the at least one contaminant present on the at least
one surface of the object based on the applying of the at least one appliable form of the cleaning composition. Further, the creating of the electromechanical reaction disassembles at least one of the organic material and the inorganic material for
cleaning the at least one surface of the object. Further, in an embodiment, the at least one contaminant may include at least one organism. Further, the at least one organism may be present on the at least one surface of the object. Further, the at
least one organism may be comprised of at least one of the organic material and the inorganic material. Further, the creating of the electromechanical reaction disassemble at least one of the organic material and the inorganic material of the at least
one organism for eliminating the at least one organism. Further, the eliminating of the at least one organism cleans of the at least one surface of the object. In further embodiments, the method 200 may include adding at least one inhibiting agent to
the carbanions. Further, the combining of the carbanions with the diluting agent may be based on the adding of the at least one inhibiting agent. Further, the at least one inhibiting agent inhibits at least one of a growth and a proliferation of the at
least one organism on the at least one surface of the object based on the applying. Further, inhibiting facilitates the cleaning of the at least one surface of the object. Further, the at least one inhibiting agent creates a hostile environment for the
at least one organism.
In further embodiments, the method 200 may include adding at least one protective agent to the carbanions. Further, the combining of the carbanions with the diluting agent may be based on the adding of the at least one protective agent.
Further, the at least one protective agent forms a protective layer on the at least one surface based on the applying. Further, forming of the protective layer prevents subsequent contaminating of the at least one surface of the object with the at least
one contaminant
Further, in some embodiments, the carbanions may be derived from at least one organic material. Further, the at least one organic material may be associated with at least one part of at least one plant.
Further, in some embodiments, the carbon atom may be associated with a hybridization state. Further, the hybridization state may be sp3 hybridization state. Further, the carbon atom in the sp3 hybridization state may be trivalent. Further,
the carbon atom in the sp3 hybridization state may include a lone pair of electrons on the carbon atom.
Further, in some embodiments, the diluting agent may include at least one a polar solvent and a nonpolar solvent. Further, at least one of the polar solvent and the nonpolar solvent may be capable of combining with the carbanions for forming
the at least one appliable form. Further, in an embodiment, the polar solvent may include water. Further, the water may be capable of combining with the carbanions for forming a first solution. Further, the at least one appliable form may include the
first solution. Further, the combining facilitates applying of the first solution of the cleaning composition to at least one surface of the object. Further, in an embodiment, the polar solvent may include at least one organic acid. Further, the at
least one organic acid may be capable of combining with the carbanions for forming a second solution. Further, the at least one appliable form may include the second solution. Further, the combining facilitates applying of the second solution of the
cleaning composition to at least one surface of the object.
FIG. 3 illustrates carbanions of the cleaning composition for facilitating cleaning surfaces of the object, in accordance with some embodiments. Further, the carbanions may be configured for performing at least one cleaning action on at least
one object. Further, the carbanions may be configured for at least one of neutralizing and removing at least one of at least one substance and at least one organism from the at least one object based on the at least one cleaning action. Further, the at
least one of the at least one substance and the at least one organism contaminates the at least one object. Further, the at least one of the at least one substance and the at least one organism pollutes the at least one object. Further, the at least
one of the at least one substance and the at least one organism infects the at least one object. Further, the at least one of the at least one substance and the at least one organism stains the at least one object. Further, the at least one organism
may include fungi, bacteria, viruses, insects, etc. Further, the insects may include pests, parasites, etc. Further, the carbanions may be configured for performing the at least one cleaning action on at least one surface of the at least one object.
Further, the at least one object may include at least one animate object and at least one inanimate object. Further, the at least one inanimate object may include at least one building, at least one article, at least one device, etc. Further, the at
least one animate object at least one human, at least one animal, at least one plant, etc. Further, the at least one animal may include at least one domestic animal, at least one farm animal, at least one wild animal, etc. Further, the at least one
cleaning action may include removing, washing, eliminating, killing, disinfecting, sanitizing, etc. Further, the carbanions may be derived from at least one organic source. Further, the at least one organic source may include the at least one plant.
Further, the carbanions may include carbon atoms extracted from the at least one plant. Further, the carbanion may include a 100% organic matter. Further, the organic matter may be organic carbon atoms. Further, at least one of a specific temperature
and a specific pressure may be applied to the carbon atoms for initiating at least one of a reduction reaction and a redox reaction. Further, the at least one of the reduction reaction and the redox reaction adds 2 electrons to the carbon atoms for
creating negatively charged carbon atoms. Further, each negatively charged carbon atom of the negatively charged carbon atoms may include 8 electrons and 6 protons and 6 neutrons. Further, the negatively charged carbon atoms may be highly negatively
charged. Further, the negatively charged carbon atoms may be the carbanions. Further, the carbanions may include a trivalent carbon atom comprising eight (8) electrons in the valence shell of the trivalent carbon atom. Further, the carbanions may be
created using physical chemistry of the carbanions. Further, the negatively charged carbon atoms may be configured for removing the at least one substance from the at least one object. Further, the negatively charged carbon atoms may be configured for
puncturing the membranes of at least one of the fungi, the bacteria, the viruses, and the insects for eliminating the at least one of the fungi, the bacteria, the viruses, and the insects. Further, the puncturing may release vital fluid of the at least
one of the fungi, the bacteria, the viruses, and the insects for the eliminating of the at least one of the fungi, the bacteria, the viruses, and the insects.
Further, in some embodiments, the at least one organic source may include biomass. Further, the carbanions may be bio-based.
Further, in some embodiments, the carbanions may be diluted using at least one diluting agent for forming a solution. Further, the at least one diluting agent may include water. Further, at least one dosage of the carbanions may be diluted
with at least one diluting volume of the at least one diluting agent. Further, the solution may be configured for performing the at least one cleaning action. Further, in an embodiment, 700 drops of the carbanions may be diluted with 1 gallon of the
water for forming the solution. Further, the 700 drops may be 2 oz. of the carbanions.
Further, in an embodiment, the negatively charged carbon atoms may attract positive atoms and release the vital fluid from the at least one of the fungi, bacteria, viruses, and insects for eliminating the at least one of the fungi, bacteria,
viruses, and insects.
Further, in some embodiments, the negatively charged carbon atoms may include particles. Further, the particles may be associated with particle size. Further, the particle size may be less than 1 nanometer in a straight solution. Further, in
an instance, the particle size may be 0.6 nm or 600 pm.
Further, in some embodiments, the carbanions may include a femto-product. Further, the femto-product 100% organic matter. Further, the organic matter may include organic carbon atoms. Further, the femto-product may be 89% New Carbon. Further, a
new carbon atom may be 100% organic. Further, the femto-product may kill the viruses by eliminating strands of nucleic acids of the viruses, either DNA or RNA of the viruses, and protective protein coat of the viruses (the capsid), or a lipid envelope of
the viruses surrounding the protein of the viruses.
Further, in an embodiment, a carbanion of the carbanions may include a single negatively charged carbon atom. Further, the single negatively charged carbon atom bonds to no other atoms except for another single negatively charged carbon atom.
Further, in an embodiment, the carbanion may be an anion in which carbon bears a formal negative charge. Further, the carbanion may include eight electrons in the valence shell of the carbon. Further, a carbon-atom of the carbanion may include
a negative charge. Further, the valence shell of a negatively charged carbon-atom may include 8-electrons. Further, the octet of the negatively charged carbon atom may be complete. Further, the negatively charged carbon atom may include an extra pair
of electrons. Further, the negatively charged carbon may be in a state of sp3 hybridization. Further, the hybrid orbitals may be directed towards the corners of a tetrahedron. Further, three hybrid orbitals may be involved in the formation of single
covalent bonds with other atoms while the fourth hybrid orbital may include a lone pair of electron. Further, the carbanion may include a pyramidal structure similar to NH3 molecule. Further, the carbon-atom may include eight electrons. Further, the
carbon-atom may be a highly reactive intermediate. Further, the carbon-atom may be readily attacked by electrophilic reagents. Further, the carbanion may be a nucleophile.
Further, in some embodiments, the carbanions may be diluted using at least one diluting agent for forming a solution. Further, the at least one diluting agent may include water. Further, at least one dosage of the carbanions may be diluted
with at least one diluting volume of the at least one diluting agent. Further, the solution may be configured for performing the at least one cleaning action. Further, in an embodiment, 700 drops of the carbanions may be diluted with 1 gallon of the
water for forming the solution. Further, the 700 drops may be 2 oz. of the carbanions.
Further, the carbanion may include "Negative Octet Energy". Further, the carbanion may be an anion in which the carbon-atom bears a formal negative charge.
FIG. 4 is a flowchart of a process 400 for producing the carbanions of the cleaning composition for facilitating cleaning of the object, in accordance with some embodiments. Further, at 402, the process 400 may include a step of extracting at
least one organic matter from at least one plant. Further, the at least one organic matter may include organic carbon atoms.
Further, at 404, the process 400 may include a step of applying at least one of a specific temperature and a specific pressure to the organic carbon atoms based on the extracting.
Further, at 406, the process 400 may include a step of initiating at least one of a reduction reaction and a redox reaction based on the applying.
Further, at 408, the process 400 may include a step of creating the carbanions based on the initiating. Further, the initiating of the at least one of the reduction reaction and the redox reaction may add 2 electrons to the organic carbon atoms
creating negatively charged carbon atoms.
FIG. 5 is a flowchart of a process 500 for producing a solution of the cleaning composition, in accordance with some embodiments. Further, at 502, the process 500 may include a step of measuring a dosage of the carbanions. Further, the dosage
may include 2 ounces. Further, the 2 ounces of the carbanion may include 700 drops of the carbanions.
Further, at 504, the process 500 may include measuring a diluting volume of at least one diluting agent. Further, the diluting volume may include 1 gallon. Further, the at least one diluting agent may include water.
Further, at 506, the process 500 may include a step of mixing the dosage of the carbanion with the diluting volume of the at least one diluting agent.
Further, at 508, the process 500 may include a step of producing the solution based on the mixing. Further, the solution may be configured for performing at least one cleaning action on at least one object.
FIG. 6 is a flowchart of a process 600 for facilitating cleaning of the object using the cleaning composition, in accordance with some embodiments. Further, at 602, the process 600 may include a step of dispensing a solution of the cleaning
composition on at least one object. Further, the at least one object may include at least one animate object and at least one inanimate object. Further, the solution may include the carbanions and at least one diluting agent. Further, the at least one
diluting agent may include water.
Further, at 602 the process 604 may include a step of performing at least one cleaning action based on the dispensing. Further, the solution may be configured for at least one of neutralizing and removing at least one of at least one substance
and at least one organism from the at least one object.
FIG. 7 is a schematic of a carbanion 700 of the carbanions, in accordance with some embodiments. Further, the carbanion 700 is an anion in which carbon bears a formal negative charge. Further, the carbanion 700 may include eight electrons in
the valence shell of the carbon. Further, a carbon-atom of the carbanion 700 may include a negative charge. Further, the valence shell of negatively charged carbon-atom may include 8-electrons. Further, the octet of the negatively charged carbon atom
may be complete. Further, the negatively charged carbon atom may include an extra pair of electrons. Further, the negatively charged carbon may be in a state of sp3 hybridization. Further, the hybrid orbitals may be directed towards the corners of a
tetrahedron. Further, three of the hybrid orbitals may be involved in the formation of single covalent bonds with other atoms while the fourth hybrid orbital may include a lone pair of electrons. Further, the carbanion 700 may include a pyramidal
structure similar to NH3 molecule. Further, the carbon-atom may include eight electrons even the carbon-atom may be a highly reactive intermediate. Further, the carbon-atom may be readily attacked by electrophilic reagents. Further, the carbanion 700
may be a nucleophile.
Although the present disclosure has been explained in relation to its preferred embodiment, it is to be understood that many other possible modifications and variations can be made without departing from the spirit and scope of the disclosure.
Thomas Cardinal Wolsey 1471-1530 Said! “Be very, very careful what you put in that head, because you will never, ever get it out.
You might have lost the ability to "UNLEARN", "Critical Thought", "Questioning". "GROUP THINKING" Creates the biggest loss to mankind,
Beware of Science!
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Atoms%20of%20Elements%20for%20Fertilizer