Provided is a powder body obtained from a water-containing organic matter having a moisture content of 20% or less, a bacterial count of mesophilic aerobic bacteria of 10.sup.5/g or less, and a maximum exothermic peak by a differential thermal analysis method of 300° C. or higher.

The present invention deals with the formation of Natural Organic Nano-Fertilizers with the chelated nano-nutrients to balance plant nutrition; improve water holding capacity, soil health improvement, sustainable productivity and quality improvement. The present invention involves production of eco-friendly and low cost process for the synthesis of nanoparticles of nano-nutrients by utilizing microorganisms comprising of two lab adapted strains of Aspergillus species, one lab adapted strain of Lactobacillus sp. and lactate, gluconate and proteinate salts as a source of nutrient leads to formation of metal nanoparticles (Zn, Mg, Fe and P) with the size of <20 nms. The present invention increases 12-20% of crop yield, stress tolerance of the crops, nutrient mobilization increases and 3 fold increase in nutrient use efficiency.

The present invention deals with the formation of Natural Organic Nano-Fertilizers with the chelated nano-nutrients to balance plant nutrition; improve water holding capacity, soil health improvement, sustainable productivity and quality improvement. The present invention involves production of eco-friendly and low cost process for the synthesis of nanoparticles of nano-nutrients by utilizing microorganisms comprising of two lab adapted strains of Aspergillus species, one lab adapted strain of Lactobacillus sp. and lactate, gluconate and proteinate salts as a source of nutrient leads to formation of metal nanoparticles (Zn, Mg, Fe and P) with the size of <20 nms. The present invention increases 12-20% of crop yield, stress tolerance of the crops, nutrient mobilization increases and 3 fold increase in nutrient use efficiency.

According to present disclosure, there is disclosed an algae growth and cultivation system that provides a cost-efficient means of producing algae biomass as feedstock for algae-based products, such as, fertilizer, feed, biofuel manufacture, and desirably impacts, nutrient recovery from waste streams for valued byproducts production, recycle water, and alternative/renewable energy production. The system as discussed herein is an integrated systems approach to wastewater treatment, algal strains selection for byproducts production, and recycle of algal biomass-processing waste or additional algae harvested as feedstock for products such as fertilizer production. Embodiments of a system as discussed herein present an economically viable algae production system and process that allows algae-derived products such as fertilizer, feed, biofuels, etc. to compete with non-organic or petroleum products in the marketplace.

A mobile, self-contained system for enhancing plant growth comprising: a mobile structure comprising a plurality of wheels so that the system can be moved; a vessel supported by the structure; a recirculating pump supported by the structure and exterior to the vessel, the pump having a first discharge line and a second discharge line; a generator supported by the structure; a vessel outlet from a bottom portion of the vessel to the pump; and an aerator for injecting air into the first discharge line; wherein the first discharge line extends from the pump directly into the bottom portion of the vessel, such that the contents of the vessel can be recirculated by the pump from the vessel outlet back into the vessel through the first discharge line and the second discharge line extends from the pump and is adapted for discharging contents of the vessel directly into an irrigation system.

A mobile, self-contained system for enhancing plant growth comprising: a mobile structure comprising a plurality of wheels so that the system can be moved; a vessel supported by the structure; a recirculating pump supported by the structure and exterior to the vessel, the pump having a first discharge line and a second discharge line; a generator supported by the structure; a vessel outlet from a bottom portion of the vessel to the pump; and an aerator for injecting air into the first discharge line; wherein the first discharge line extends from the pump directly into the bottom portion of the vessel, such that the contents of the vessel can be recirculated by the pump from the vessel outlet back into the vessel through the first discharge line and the second discharge line extends from the pump and is adapted for discharging contents of the vessel directly into an irrigation system.

A process for the preparation of a soil inoculating composition comprising the steps of a) loading a vermicompost into a tank, b) adding a sufficient amount of water and molasses to vermicompost, c) breeding of microorganism in the mixture obtained in the step b), by adjusting the temperature to a range between 25-27° C. and by providing air into the mixture, d) forcing microorganism in the mixture obtained in the step c), to dormant state by d) adding a sufficient amount of molasses, e) bottling the composition obtained in the step d), for storage, f) resuscitating of microorganism in the stored composition from the dormant state to active state by diluting the composition with a sufficient amount of water before soil inoculation. An apparatus for producing soil inoculating composition comprising two concentric tanks wherein the inner tanks (104) holds the composition and the outer tank (101) acting as an heating system holds a liquid kept at a desired temperature by an heat control system (106).

A process for the preparation of a soil inoculating composition comprising the steps of a) loading a vermicompost into a tank, b) adding a sufficient amount of water and molasses to vermicompost, c) breeding of microorganism in the mixture obtained in the step b), by adjusting the temperature to a range between 25-27° C. and by providing air into the mixture, d) forcing microorganism in the mixture obtained in the step c), to dormant state by d) adding a sufficient amount of molasses, e) bottling the composition obtained in the step d), for storage, f) resuscitating of microorganism in the stored composition from the dormant state to active state by diluting the composition with a sufficient amount of water before soil inoculation. An apparatus for producing soil inoculating composition comprising two concentric tanks wherein the inner tanks (104) holds the composition and the outer tank (101) acting as an heating system holds a liquid kept at a desired temperature by an heat control system (106).

A method for increasing the fertility of soil for agricultural crop production by producing a biofertilizer containing one or more selected strains of nitrogen fixing cyanobacteria that are compatible with the type of soil and environmental conditions where the biofertilizer is to be applied and rhizobacteria, and applying the biofertilizer to such soil at a rate that is sufficient to accelerate the fertilization performance of the soil for the growth of agricultural products, and to increase the net terrestrial sequestration of CO2.

A method for increasing the fertility of soil for agricultural crop production by producing a biofertilizer containing one or more selected strains of nitrogen fixing cyanobacteria that are compatible with the type of soil and environmental conditions where the biofertilizer is to be applied and rhizobacteria, and applying the biofertilizer to such soil at a rate that is sufficient to accelerate the fertilization performance of the soil for the growth of agricultural products, and to increase the net terrestrial sequestration of CO2.