top of page

SNX30+ for Better Soil and Plant Health produces 16.1 bpa more yield and profit when used as a seed treatment

Here is the world's only supplement for better soil and plant health and more yield using 4 modes of action (building blocks) that intensifies:

1)   a full spectrum of plant and soil microbes...

2)  Pink-Pigmented Facultative Methylotrophs (PPFMs)...

3)  VOCs...

4)  and Terpenes all working together to help give your crops darker soil and provide more moisture, more warmth in cold temps, and more life...

SNX30+ can also be used as a low cost supplement with a 15:1 ROI or better for macros, micros, and biostimulants in most crop applications with no change in farming practice.

 

Note that SNX30+ has none of the negative characteristics such as heat, cold, and time constraint issues like most biological inputs.

​

SNX30+ is also an energy supplement like SmartNute's flagship product, the SNX30 fertilizer supplement (less fertilizer + more yield). In addition to a seed treatment, 

 

Let's begin with the intensified microbe supplement component and how it contributes to SNX30+.

 

Just like SNX30 intensifies your NPK and micros to increase yield or reduce the amount of fertilizer you apply, or intensify the residuals already present in your field, SNX30+ intensifies the microbes already present in your soil and plants plus many biologicals you add.

 

As you may already know, microbes play crucial roles in farming, providing numerous benefits that contribute to soil fertility, plant growth, and overall ecosystem health. Here are some key benefits of microbes in agriculture:

microbes B.PNG

The soil is a living ecosystem providing the environment for a wide variety of intensified microbes.  More microbes equals darker soil benefits.

Nutrient Cycling:

Microbes, particularly bacteria and fungi, are essential for breaking down organic matter in the soil. They decompose dead plant material and release nutrients back into the soil in forms that plants can absorb.

microbes C.PNG

Plant roots excrete organic substances such as sugar, amino acids and other vital nutrients to attract a chain of intensified soil microbes.

microbes E.PNG

These intensified microbes live on the root surfaces or can penetrate into the roots through the root hairs and excrete hard to digest substances in forms for the plants to absorb. 

microbes G.PNG

SNX30+ intensified microbes can also coat the plant roots with a bio-glue substance that helps maintain moisture in the root zone during harsh drought conditions.

Soil Oxygen help through microbes:

Soil microbes play a role in influencing oxygen availability in the soil, though they don’t add oxygen directly in the way that plants do through photosynthesis. Instead, they support soil structure and nutrient cycling, which can indirectly influence soil oxygen levels in several ways:

 

1. 

Soil Structure Improvement: Microbes produce substances that help bind soil particles together, improving soil structure and creating air pockets. This helps oxygen flow into the soil, which is beneficial for plant roots and other soil organisms that need oxygen.

 

2. 

Decomposition and Nutrient Cycling: Microbes decompose organic matter, breaking it down into simpler compounds. During this process, they consume oxygen to break down these materials, releasing nutrients that plants can use. This cycling of nutrients makes the soil more fertile, indirectly promoting plant growth, which in turn adds more organic matter (such as root exudates) to the soil and can improve oxygen content over time.

 

3. 

Symbiosis with Plants: Certain microbes, like mycorrhizal fungi, form symbiotic relationships with plant roots, improving the plant’s nutrient and water uptake. Healthier plants with robust root systems can contribute more organic matter to the soil, enhancing soil structure and oxygen diffusion.

 

Soil microbes don’t "add" oxygen in the same way as photosynthesizing plants, but their activities create favorable soil conditions for oxygen to move more easily through the soil, benefiting plant roots and other aerobic organisms.

 

Nitrogen Fixing microbes:

Certain bacteria, such as the Rhizobium species, form symbiotic (harmonious) relationships with leguminous plants. These bacteria can fix atmospheric nitrogen into a form that plants can use, promoting nitrogen availability and reducing the need for synthetic fertilizers. 

 

Phosphorus Solubilizing microbes:

Phosphate-solubilizing bacteria release phosphorus from organic and inorganic sources, making it more accessible to plants. This enhances the plant's ability to take up phosphorus.

 

Disease Suppression microbes:

Beneficial microbes act as biocontrol agents, suppressing the growth of harmful pathogens. Some fungi and bacteria microbes produce compounds that inhibit the growth of plant pathogens, providing a natural defense mechanism.

 

Enhanced Nutrient Absorption microbes:

Mycorrhizal fungi form symbiotic associations with plant roots, extending the root system's reach and enhancing the plant's ability to absorb water and nutrients, particularly phosphorus.

 

Improving Soil Structure microbes: 

Intensified microbial activity, especially that of certain types of bacteria and fungi, contributes to the formation of soil aggregates (primary soil particles). This improves soil structure, porosity and water retention, while promoting a healthier root environment.

 

Plant Growth-Promoting Substances:

Certain intensified microbes produce plant growth-promoting substances like auxins and cytokinins, which stimulate plant growth and development.

 

Degrading Organic Pollutants: 

Intensified microbes break down and degrade organic pollutants in the soil, contributing to environmental remediation.

 

Stress Tolerance:

Intensified microbes help plants tolerate environmental stresses such as drought, salinity and disease. They can enhance the plant's resilience under challenging conditions.

 

Composting:

Intensified microbes are crucial in the composting process, breaking down organic matter into a nutrient-rich humus that can be used as an organic fertilizer.

 

Biofertilizer: 

This intensified microbial-based product contains beneficial microorganisms that enhance nutrient availability and promote plant growth, and can be used as an alternative or supplement to chemical fertilizers.

 

Harnessing the potential of these intensified SNX30+ microbes can be the lifeblood of a regenerative and sustainable approach to farming. It can lead to improved soil health, increased crop yields, reduced reliance on synthetic inputs and chemicals and contribute to environmentally friendly and economically viable farming practices.

 

The SNX30+ microbial supplement brings together these components to intensify microbe colonies by:

1) 

Supplementing / intensifying microbes as biological digesters to compost corn and sugarcane stalks, manure, residue and similar biologicals like contaminated waters and soils.

 

2) 

Supplementing / intensifying mycorrhizal fungi as beneficial soil microbes and colony forming units.

 

3) 

Supplementing / intensifying a microbe potassium growth enhancement.

 

4) 

Supplementing / intensifying a biological inoculant for drought-stressed soils to establish even more populations of beneficial microbes.

 

5) 

Supplementing / intensifying a rhizobacteria and phosphorus solubilizer to also promote additional beneficial soil microbe populations. 

 

6) 

Supplementing / intensifying a different population of microbes to help build soil carbon.

 

7) 

Supplementing / intensifying microbes to increase a crop’s tolerance to extreme field situations like salt, drought, cold and heat.

In general, these intensified microbes and beneficial strains of bacteria and fungi combinations are specifically designed to increase yield by improving nutrient uptake, nitrogen fixing and promoting faster emergence. But, intensified microbes are only one of the 4 major building blocks of SNX30+.

Pink-pigmented facultative methylotrophs (PPFMs)

​

These bacteria benefit farmers due to their importance in seed germination, yield, pathogen resistance and drought stress tolerance. Now, the SNX30+ supplement is available to intensify PPFMs' already powerful benefits.

When foliar spraying PPFMs, this results in increased PPFM populations which in turn cause a higher concentration of bacterially produced cytokinin -- increased cytokinin contributes to improved yield.

Pink-pigmented facultative methylotrophs (PPFMs) offer other potential benefits in agriculture, primarily through their unique metabolic capabilities and interactions with plants. Here are some of the potential benefits of PPFMs:

​

Methanol Utilization:

Intensified PPFMs have the ability to utilize methanol as a carbon and energy source. This can be advantageous in environments where methanol is present, providing an alternative carbon source for microbial growth.

​

Plant Growth Promotion:

Intensified PPFMs can promote plant growth. They can enhance nutrient availability and uptake, leading to improved plant development and increased crop yields.

Biocontrol of Pathogens:

Intensified PPFMs can act as biocontrol properties, helping to suppress the growth of plant pathogens. By competing for resources and producing antimicrobial compounds, they contribute to plant health and reduce the incidence of diseases.

 

Stress Tolerance:

Intensified PPFMs can enhance plant stress tolerance, including resistance to stress such as drought and salinity. This benefit is valuable in agricultural systems where plants face challenging environmental conditions.

 

Nutrient Cycling:

Intensified PPFMs contribute to nutrient cycling in the soil by decomposing organic matter. This process releases nutrients back into the soil, making them available for plant uptake.

​

Root Development:

Intensified PPFMs can influence root development, leading to increased root biomass and improved nutrient and water absorption by plants. Enhanced root systems contribute to greater nutrient uptake and overall plant health and vigor.

Bioremediation: 

Intensified PPFMs can help in the bioremediation of environments contaminated with methylated pollutants. Their ability to metabolize methanol and related compounds can contribute to the breakdown of pollutants in the soil.

 

Enhanced Phytoremediation: 

Intensified PPFMs can enhance phytoremediation processes in plants, as they can break down pollutants taken up by plants, contributing to environmental cleanup efforts.

 

Sustainable Agriculture:

The use of intensified PPFMs aligns with regenerative and sustainable farming practices by reducing the reliance on synthetic chemicals. Intensified PPFMs can contribute to a more balanced and resilient agricultural ecosystem.

 

The use of PPFMs in agriculture is an area of ongoing research and positive discovery. Their unique metabolic capabilities and potential contributions to plant health make them top candidates for desired crop management. As research progresses with SNX30+, more insights into their specific applications and benefits are most likely to emerge. 

In addition to intensified microbe and PPFM supplements, intensified VOCs and terpene supplements are also included in SNX30+.

 

Science has finally come to the rescue of farming with many new and organic inputs. Here are two new additions that are at the top of the list with SNX30+. These intensified VOCs and terpene supplements offer amazing abilities to better your crop's health and yield without synthetic chemicals.

Volatile Organic Compounds (VOCs)

 

Volatile Organic Compounds (VOCs) play various roles in the growth and development of plants, including corn and soybeans. Here are some potential benefits:

 

Plant Defense Mechanisms:

 

Indirect Defense:

Intensified VOCs emitted by plants can act as signals to attract natural enemies of herbivores, serving as a form of indirect defense. These compounds can attract predators and parasites that help control herbivore populations and help protect the plants.

 

Direct Defense:

Some Intensified VOCs have antimicrobial properties and can directly inhibit the growth of pathogens to provide a form of protection against diseases.

​

Plant Communication:

 

Inter-plant Signaling: 

Intensified VOCs can be involved in signaling between plants. In response to stress or herbivory, plants may release Intensified VOCs that can be sensed by nearby plants, inducing them to activate defense mechanisms.

​

Abiotic Stress Tolerance:

 

Stress Response: 

Intensified VOCs can be produced by plants in response to various environmental stresses such as drought, high temperature, or pollution. These compounds may help the plants cope with stress and enhance their overall resilience.

 

Allelopathy:

 

Chemical Interactions:

Some intensified VOCs released by plants can have allelopathic effects, influencing the growth and development of neighboring plants. This can either be inhibitory or stimulatory, depending on the specific compounds involved.

 

Root Development:

 

Root Growth Promotion:

Certain intensified VOCs emitted by microbes in the rhizosphere (root zone) can promote root growth and enhance nutrient uptake, contributing to the overall health and productivity of the plants.

 

Floral Scent and Pollination:

 

Attracting Pollinators: 

Intensified VOCs, especially floral scents, play a crucial role in attracting pollinators. This is important for the reproductive success of plants, including corn and soybeans.

 

Beneficial Microbe Interactions:

 

Microbial Communication:

Intensified VOCs are involved in communication between plants and beneficial microbes in the soil. This interaction can enhance nutrient availability and improve the overall health of the plants.

 

Adaptation to Changing Environments:

 

Stress Adaptation:

The production of intensified VOCs can be a part of the plant's adaptive response to changing environmental conditions, helping them survive and thrive in diverse ecosystems.

Terpenes

Terpenes are the mediators of plant-to-plant communication. What, exactly, does that mean? Terpenes help plants “talk” to each other for optimal growth through environmental protection.

 

Intensified terpenes deliver “fix-it” information about environmental issues not only inside each plant but also among plant groups called communities. During a plant+insect and plant+pathogen meetup, plants influence each other through terpene biological crosstalk.  And, plants are equally sensitive to give OR take information by way of these terpene signals. 

 

Intensified terpenes can protect plants from various chemical and natural stresses and are important communication signals between plants and other organisms including insects, fungi, and bacteria. In certain environments including pathogen (bad disease) infection or microbial communities, specific emission patterns develop from these environments and healthy terpenes have the “troops” to handle the battle.

 

Intensified microbes can use intensified terpenes as their own sole carbon source, thus quenching the signals by simply “feeding” on them. Intensified microbes emit diverse intensified terpenes that have chemical structures largely similar to plant-released terpenes. So now you can see that plants and microbes can speak the same language after a little practice -- just like humans do to better communicate.

bottom of page