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.

A process for fast humification and non-fermentative bio-stabilization of solid and/or liquid, vegetal and/or animal organic material, comprising the following phases: an initial phase of preparation and pre-treatment of said organic material, for preparing activated and mixed material brought to a substantially neutral pH; a next phase wherein said activated and mixed material at a substantially neutral pH is treated in a reactor, in which it is re-mixed and irradiated with radio frequencies conveyed by waveguides for a given time; a final phase of post-processing the material treated in the reactor, adapted for producing a biostabilized organic product.

The Earthginuity Composting System is an organic waste composting system. It consists of three steps/components. The first step is using a free-standing cylindrical tube that goes in the kitchen. Organic waste goes into the tube. The second step is the Phase 1 Bin. It is a square-shaped plastic bin that sits on raw earth, and it's about thirty three gallons in volume. It has drainage holes at the bottom and two pegs protruding from the front to serve as anchors for dumping. The final component is the two Earth Grids. They are three by three feet, sandbox-like squares with NO bottoms and liquid-tight lids. The lack of a bottom to the Earthgrids allows for sitting on raw earth to attract ground bugs/bacteria. The lids have rain holes. You can open, close, and empty the Earth Grids with a Shepherd's Staff (hooked pole).

A composting bin for breaking down organic material includes a container having an interior and an opening. The interior includes a plurality of regions, including a first region and a second region. The first region and the second region are configured to support decomposable organic material. In operation, a user positions decomposable organic material in, for example, the first region. The user then provides a composting animal in the first region. The user covers the composting bin to inhibit light from entering the composting bin. Upon completion of the composting process, the user causes the composting animal to move from the first region to the second region. The user causes the composting animal to move from the first region to the second region by allowing light to enter the first region, and/or providing food in the second region while denying food in the first region.

Disclosed herein is an insect sorting system that includes a conveyor stage having a drive unit, a grasping surface movably coupled with the drive unit and having textured surface elements, and a diverter that is configured to remove insects from the grasping surface.

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.

Various examples are provided for in situ growth of subsurface structures using bioinspired mineralization. In one example, among others, a method for growth of a subsurface structure includes introducing a first aqueous mineral salt reactant and a second aqueous mineral salt reactant comprising a polymeric additive into a soil substrate. The first and second aqueous mineral salt reactants can combine to form a polymer-induced liquid-precursor (PILP) phase that initiates in situ mineralization in the soil substrate. Solidifying the mineralization can form a subsurface structure in the soil substrate. Multiple applications of aqueous mineral salt reactants can be introduced to adjust the thickness of the mineralization or for layers of coatings.

A process is disclosed for creating biologically active soil or horticulture media for growing plants, wherein a fibrous carbon source such as coconut coir in a predetermined particulate form is mixed with fertilizers and other biological nutrients, inoculated with a biologically active substance such as worm castings and then aged or cured in an oxygen rich aerobic process. After which additional nutrients can be added to tailor the aged media for a specific use. Various apparatus with which to conduct the aging process are also described. In a variation of the process used soil or horticulture media is recharged by first composting at a high temperature to remove harmful and unwanted items, its contents are evaluated, nutrients are added, and it is then aged in an aerobic process.

A process is disclosed for creating biologically active soil or horticulture media for growing plants, wherein a fibrous carbon source such as coconut coir in a predetermined particulate form is mixed with fertilizers and other biological nutrients, inoculated with a biologically active substance such as worm castings and then aged or cured in an oxygen rich aerobic process. After which additional nutrients can be added to tailor the aged media for a specific use. Various apparatus with which to conduct the aging process are also described. In a variation of the process used soil or horticulture media is recharged by first composting at a high temperature to remove harmful and unwanted items, its contents are evaluated, nutrients are added, and it is then aged in an aerobic process.

A method for restoring a contaminated site comprising the steps of: undertaking an amendment of a contaminated site by applying a first catalyst and a second catalyst to the contaminated site; and incorporating the first catalyst and the second catalyst into a soil on the contaminated site to form an amended contaminated site, wherein the contaminated site has excessive acidity, alkalinity and/or sodic contamination, wherein amending the contaminated site with the first catalyst and the second catalyst assists in the restoration of the amended contaminated site by transferring a biological energy generation mechanism to the amended contaminated site which improves the capacity of the amended contaminated site to balance a hydrogen cycle and hydrogen exchange between biotic and abiotic sources.