NanograpH

Greensmiths, Inc. is thrilled to unveil our latest breakthrough – NanograpH.

NanograpH is a unique revolutionary fertilizer. The patented process produces a totally different methodology to any controlled release or enhanced efficiency fertilizer (EEF).

Firstly, the graphite coating is organic, inert, and is not utilized by the plant. Secondly, at four billion years old, it does not degrade in the soil.

And thirdly, the mode of action is by its high redox potential that favors beneficial bacteria in the nitrification cycle that lowers atmospheric loss and nitrate leaching.

However, let’s dive even deeper. The recent development of metagenomics in soils analyzes all microbial activity, nitrification and denitrification function illustrates the values of graphite addition.

Chemolithotrophy is the oxidation of inorganic chemicals for the generation of energy. Graphite is an electron donor. It was thought that ammonium thiosulfate might be a nitrification inhibitor because thiosulfate as a reduced form of sulfur is also a chemoautotroph. The electrons are passed off to carriers of electron transport generating a proton motive force that is used to generate ATP (Adenosine Tripolyphosphate).

A Diamond Lasts Forever

Graphite and diamonds are both crystalline forms of pure carbon. The permanence of the carbon bonds separate them from all other forms of carbon.

Specifically, the importance of soil carbon is well documented. Soil metagenomics illusidates the carbon function. Specific application to nitrification and denitrification has been used to evaluate graphite, graphene, humic acid, biochar, pig manure, and chemical controls. All of the products have proven values and limitations.

Graphene is a single, one atom thick layer of graphite; graphite is essentially made up of hundreds of thousands of layers of graphene. Subsequently, they have the same properties, except in size. However, graphene cannot be held in the soil and possibly migrate into groundwater. The strength of graphene makes it so sharp; its physical presence and longevity could be more dangerous than micro-plastics.

Biochar requires energy to produce and requires very high volumes to produce results in nitrification.

Pig and other manures have water quality implications and high volumes require to supply nutrition and soil improvement.

Humic acids and fulvic acids are expensive and can move from the rhizosphere.

Expensive EEFs

Chemicals that provide enhanced efficiency to control denitrification are expensive, have mixed results in performance and are not natural to the soil system. You can read more on this here: Read More

Graphite provides proven results to the rhizosphere at low cost when used as a fertilizer coating. It is natural, organic, and functions through redox potential (redox conditions regulate many of the biogeochemical reactions in the soil system and influence the physical and morphological properties, plus changes in functional dynamics of microbes).

Carbon vs. Graphite

Carbon

Graphite

Definition

Carbon is a chemical element having the atomic number 6 and chemical symbol C.

Graphite is a stable allotrope of carbon.

Chemical Category

A nonmetallic chemical element.

An allotrope.

Electrical Conductivity

Except graphite, other forms cannot conduct electricity.

An allotrope. Can conduct electricity due to the presence of free electrons.

Nanotechnology

Graphite is the most common form of carbon used in nanotechnology.

The graphene sheets of graphite are useful in nanotchnology.

Structure

Can occur in different allotropic forms in nature such as graphite, diamond, charcoal, etc.

A network of carbon atoms in which each carbon atom has three covalent bonds around them (with other carbon atoms) and an electron cloud with can conduct electricity.

Energy is the basis for life. It cannot be created or destroyed, only transferred. NanograpH supplies niitrogen with energy.

Metagenomic Testing and NanograpH

Proven by metagenomic testing, NanograpH offers total organic biological control of the soil microbiome.

Metagenomic soil testing is a powerful tool that provides several benefits for understanding and analyzing soil microbiomes. Greensmiths, Inc. and our distributors, use this detailed testing to formulate custom blends of fertilizer. Blends are created based on each customers’ specific needs and soil requirements.

Some key benefits of metagenomic soil testing include:

Comprehensive analysis: Metagenomic soil testing provides a comprehensive analysis of the microbial communities present in the soil. It allows for the identification and characterization of diverse microorganisms, including bacteria, fungi, archaea, viruses, and other microbial species. This can provide a more complete picture of the soil ecosystem. This information can tell us its potential impact on plant health and nutrient cycling.

Functional potential assessment: Metagenomic soil testing not only identifies the microbial species but also assesses their functional potential. By analyzing the DNA and genomes of the microorganisms present in the soil, researchers can determine the genes and metabolic pathways these organisms possess. This information can help predict the capabilities and roles of the microbial community in nutrient cycling, carbon sequestration, disease suppression, and other soil processes.

Insight into soil health and fertility: Metagenomic soil testing can provide valuable insights into the health and fertility of the soil. By evaluating the composition and diversity of the microbial community, it can indicate whether the soil is well-balanced and thriving. Additionally, it can tell us if it is suffering from imbalances or degradation. This information can guide soil management strategies and help optimize nutrient cycling, organic matter decomposition, and overall soil fertility.

Benefits of Metagenomic Testing

Disease and pest management: The analysis of soil microbial communities through metagenomic testing can aid in disease and pest management in agriculture. Certain microorganisms can act as biocontrol agents, suppressing soilborne pathogens and pests. Understanding the composition and functional potential of the soil microbiome can help identify beneficial microorganisms. Thus, guiding the development of microbial-based treatments or biofertilizers to combat soilborne diseases and pests.

Soil remediation and restoration: Metagenomic soil testing has applications in soil remediation and restoration. By assessing the microbial composition and functional potential of contaminated or degraded soils, it is possible to determine the presence of specific microorganisms. Being able identify these microorganisms allows us to identify the ones capable of degrading pollutants or improving soil quality. This information can inform strategies for bioremediation or soil restoration, enhancing the success and efficiency of these processes.

Overall, metagenomic soil testing provides a wealth of information about the complexity and functioning of soil microbiomes. It can inform agricultural practices, soil management strategies, disease control, and environmental restoration efforts, ultimately contributing to improved soil health, crop productivity, and sustainable land management.

Lastly, we use this detailed information to customize your fertilizing plan. Following these guidelines will provide significant improvement to your turfgrass or crops. The Greensmiths difference is undeniable. NanograpH is revolutionary in every way. Review our website to learn more.

Contact a local distributor and ask for Greensmiths products by name.