A system for decontaminating/neutralizing breathable air and surfaces in an occupied enclosed space, i.e., agricultural greenhouse, includes mounting an atmospheric hydroxyl radical generator along an inside surface of the atmospheric hydroxyl radical generator having respective opposite air inlets and air outlets. The hydroxyl radical generator includes a polygonal housing supporting a plurality of spaced crystal-spliced UV optics, which are tubular, medical grade pure quartz optics to emit/irradiate ultraviolet in the nanometer wavelength/ultraviolet spectrum of between 100 and 400 nanometers for deactivating and neutralizing atmospheric chemicals and pathogens in breathable air and surfaces. The hydroxyl radicals contact the walls of the reaction chamber housing. The hydroxyl radicals become created and excited to react quickly with impurities including VOC, virus, bacteria and fungi, rendering them inactivated and neutral. The breathable air passes through the polygonal housing and is decontaminated and neutralized of impurities before entering the occupied enclosed space.

An objective of the present invention is to provide a method of producing artificial bio-soil aggregates based on foamed concrete for plant growth that can ensure sufficient moisture and plant nutrients for the habitat of plants in non-soil conditions; obtain a lightweight, durable, and deep soil layer, and continuously provide a favorable environment for plant growth.

To achieve the above objective, according to the present invention a paste is prepared by mixing cement with an admixture, such as ochre and burnt-furnace slag; foamed concrete is formed by adding foam bubbles with an appropriate foaming rate to said paste, thereby producing soil concrete. When the foamed concrete is used, a designated compressive strength can be ensured and a number of pore spaces are formed, which allow the air to be sucked and expelled therethrough and store moisture therein. Also, hydrogel that is incorporated into the foamed concrete may supply nutrients required for plant growth, improve pest resistance, and store and supply a large amount of water.

A soil-less biodegradable and porous rigid foam substrate for cultivating plants that has been formed of a heterogeneous matrix of organic fibers pasteurized with organic matter and natural minerals, and then contacted with a fungus, resulting in a biocomposite foam with excellent capillary dynamics, the whole of which does not compact and whose organic bio-composition favors the proper micro-biological activity upon a plants' rhizosphere. The preferred embodiment is to grow said substrate inside a waxed hexagonal prism shaped box, and around an externally accessible means of internal aeration, for approximately 3-5 days, and then to deactivate the live fungus in said biocomposite foam by exposure to microwave radiation.

Described herein are methods, compositions, products, and processes that utilize bioceramics in traditional agricultural and hydroponic systems. The bioceramics are utilized in powder form, as films, as aerosols, as water based treatment systems, or in solid forms. The methods and bioceramic compositions described here are also used for growing a Cannabis plant. One or more cannabinoids within the plant can be used in therapeutic compositions for the treatment of glaucoma, AIDS wasting syndrome, neuropathic pain, cancer, multiple sclerosis, chemotherapy-induced nausea, and certain seizure disorders.

Described herein are methods, compositions, products, and processes that utilize bioceramics in traditional agricultural and hydroponic systems. The bioceramics are utilized in powder form, as films, as aerosols, as water based treatment systems, or in solid forms. The methods and bioceramic compositions described here are also used for growing a Cannabis plant. One or more cannabinoids within the plant can be used in therapeutic compositions for the treatment of glaucoma, AIDS wasting syndrome, neuropathic pain, cancer, multiple sclerosis, chemotherapy-induced nausea, and certain seizure disorders.

Described herein are synergetic preparations for enhancing the water holding capacities of solid plant growth medium, consisting of a) ground zeolite, and b) powdered hypocalcic Montmorillonite expanse clay, and optionally c) granular expansive clay. Wherein the ratio of zeolite to Montmorillonite is between 1 to 0.25 and 1 to 30, and the ratio of powdered hypocalcic Montmorillonite expanse clay in the total amount of expansive clay is between 2 and 100%. Further optionally including components which aid product attractiveness, extend soil water retention, and assist plant and soil microbe growth.

Described herein are synergetic preparations for enhancing the water holding capacities of solid plant growth medium, consisting of a) ground zeolite, and b) powdered hypocalcic Montmorillonite expanse clay, and optionally c) granular expansive clay. Wherein the ratio of zeolite to Montmorillonite is between 1 to 0.25 and 1 to 30, and the ratio of powdered hypocalcic Montmorillonite expanse clay in the total amount of expansive clay is between 2 and 100%. Further optionally including components which aid product attractiveness, extend soil water retention, and assist plant and soil microbe growth.

A horticultural growing medium including a support matrix, the support matrix present in an amount between 60 and 80% by weight and an inorganic component. The organic component includes a moss component including at least 50% by weight moss from the Sphagnum genus is composed of at least 25% hyaline cells; between 30 and 50% by weight plant derived cellulose fiber component including alone or in any combination: coir, bamboo, hemp, cocoa fiber, rice hulls, and mixtures thereof; and between 0 and 15% cork fiber. The inorganic component includes a particulate igneous volcanic material component including at least one of amorphous volcanic glass, volcanic rock. The horticultural growing medium also includes an organic soil constituent present in an amount between 20 and 40% by weight that includes between 30% and 70% by weight humus soil; between 30% and 70% vermicompost; and up to 5% by weight mammalian derived fecal matter.

A horticultural growing medium including a support matrix, the support matrix present in an amount between 60 and 80% by weight and an inorganic component. The organic component includes a moss component including at least 50% by weight moss from the Sphagnum genus is composed of at least 25% hyaline cells; between 30 and 50% by weight plant derived cellulose fiber component including alone or in any combination: coir, bamboo, hemp, cocoa fiber, rice hulls, and mixtures thereof; and between 0 and 15% cork fiber. The inorganic component includes a particulate igneous volcanic material component including at least one of amorphous volcanic glass, volcanic rock. The horticultural growing medium also includes an organic soil constituent present in an amount between 20 and 40% by weight that includes between 30% and 70% by weight humus soil; between 30% and 70% vermicompost; and up to 5% by weight mammalian derived fecal matter.

The present disclosure provides a preparation method for a seedling substrate using residues from Populus forests as raw materials and an application. The preparation method for a seedling substrate includes the following steps: crushing Populus fallen leaves into Populus fallen leaf scraps; crushing Populus dead branches into Populus dead branch scraps; mixing the Populus fallen leaf scraps, the Populus dead branch scraps, chicken manures and garden soil to obtain a mixture; adding effective microorganisms (EM) bacterial powder to the mixture for fermentation; and adding perlite during the fermentation to obtain a seedling substrate. The seedling substrate provided in the present disclosure is rich in microorganisms and comprehensive in nutrients, does not require additional fertilizers in a seedling stage, and is capable of promoting the growth of forest seedlings.