A fortifier for growth and flowering in horticulture, trees and ornamental plants, aromatic plants and fruit trees, from wastewater from brewer's yeast with a very low protein concentration. The method including the step of: filtered by 80 μm; magnetic treatment of the liquid; addition of 0.1 to 20 g/l phosphate and 10 to 20 g/l glycose. Fermentation is carried out keeping the free amino acid content greater than 0.1%, the content of Mg.sup.+2 greater than 0.1%, total nitrogen, phosphate, and potassium below 3.0%, the content of protein from 0.5% to 1.0% and EDTA from 0.02% to 0.2%, all by dry matter weight; addition of microbes from the environment; at temperatures of 15° C. to 40° C. with gentle agitation, for 24 hours to 30 days; subsequent filtering and pH adjustment. It has been found to be effective in various crops.

The current application relates to a liquid fertilizer composition for application to plants and soils, comprising an autothermal thermophilic aerobic bioreaction product from a liquid fraction of poultry manure and further to a method of improving health and productivity of a plant or crop using said composition and to a method of conditioning soil using said composition.

The current application relates to a liquid fertilizer composition for application to plants and soils, comprising an autothermal thermophilic aerobic bioreaction product from a liquid fraction of poultry manure and further to a method of improving health and productivity of a plant or crop using said composition and to a method of conditioning soil using said composition.

An organic composition for decomposing bodily remains including a composite mixture of compost, peat, sulfur, and gypsum. The composite mixture is configured to combine with the bodily remains to decompose the bodily remains. The combined mixture has a reduced pH for reducing the detrimental effects of the bodily remains on the environment.

An organic composition for decomposing bodily remains including a composite mixture of compost, peat, sulfur, and gypsum. The composite mixture is configured to combine with the bodily remains to decompose the bodily remains. The combined mixture has a reduced pH for reducing the detrimental effects of the bodily remains on the environment.

For qualitative and quantitative production of biogas, nanoparticles and use of macroalgae when added to AD feedstock at proper concentration, temperature and time of digestion can bring a revolution to meet the future needs of energy. The process of biofuel production can be altered by using various nanomaterials in various ways, such as by improving the stability of cellulose enzymes, enhancing the catalytic production of biohydrogen, and improving biological and chemical digestion. This influence of nanoparticles on the process is determined by their distinct catalytic activity based on structure, shape and size which is complementary to the relevant process. The addition of seaweed in the AD feedstock improves biogas output and digestate quality thus enhancing the economic viability with the simultaneous positive impact of reducing global warming.

A biologically active compost is manufactured using a sterile commodity compost, a set of cultures and inoculants, and a disbursed portion of an earlier biologically active compost. The biologically active compost is manufactured from the sterile commodity compost, infusing it with the cultures and inoculants, and combining it with the disbursed portion of an earlier biologically active compost. The resultant biologically active compost includes a compost substrate suitable for growing biological material, and a microbiome permeating the substrate, the microbiome having a collection of microfauna with a wide biological diversity or other statistical variance. The microbiome includes archaea, aerobic or anaerobic bacteria, amoebae or protozoa, fungi, nematodes, microarthopods, or plant or animal fragments, well in excess of amounts that can survive the thermophilic process for producing the commodity compost.

A method of processing biological solids includes blending a sludge with calcium oxide and delivering the blended sludge and calcium oxide to a pressurized container; injecting, into the blended sludge and calcium oxide in the pressurized container, an additive capable of exothermic reactions with the calcium oxide; regulating pH in the pressurized container to produce class A biological solids from the sludge; and pumping the blended sludge, calcium oxide, and additive from the pressurized container to a reactor. A system used for this process include sources of calcium oxide and biological solids, an additive injector, and a pressurized reactor.

A method of processing biological solids includes blending a sludge with calcium oxide and delivering the blended sludge and calcium oxide to a pressurized container; injecting, into the blended sludge and calcium oxide in the pressurized container, an additive capable of exothermic reactions with the calcium oxide; regulating pH in the pressurized container to produce class A biological solids from the sludge; and pumping the blended sludge, calcium oxide, and additive from the pressurized container to a reactor. A system used for this process include sources of calcium oxide and biological solids, an additive injector, and a pressurized reactor.

The invention concerns a combination of ingredients comprising a fraction of palm, a fraction of bamboo, a fraction of an aquatic plant, a fraction of tropical forest tree, milk, feather and urine and/or earthworm excrements, said ingredients having undergone fermentation, as well as its use as phytosanitary composition and in particular fertilizer and the manufacture of a sanitary composition.