The present invention relates to a method for producing consumer-ready vegetables, mushrooms or herbs, comprising the steps of culturing vegetables, mushrooms or herbs in a closed container under suitable growing conditions until maturity; and transferring the container with the mature vegetable, mushrooms or herb to a retail outlet. The culturing of the vegetables, mushrooms or herbs until maturity takes suitably place in or in the vicinity of the retail outlet. The invention further relates to a set for performing the method and to the container comprising the mature vegetables, mushrooms or herbs.

This present invention is directed to a method for the production and use of the leaf and/or leaves and/or stem(s) and/or stalk(s) of plants of the cannabis species for animal, microbial, bacteria, fungi or human consumption as a food, supplement, medicine, beverage.

This present invention is directed to a method for the production and use of the leaf and/or leaves and/or stem(s) and/or stalk(s) of plants of the cannabis species for animal, microbial, bacteria, fungi or human consumption as a food, supplement, medicine, beverage.

The present disclosure relates to horticultural hydrogels for growing plants and/or fungi, and more particularly to hydrogel-based substrates for the germination, growth, and/or sporulation of those plants and/or fungi.

The present disclosure relates to horticultural hydrogels for growing plants and/or fungi, and more particularly to hydrogel-based substrates for the germination, growth, and/or sporulation of those plants and/or fungi.

Provided is a method for cultivating low potassium leafy vegetables at high yield without causing growth failure due to potassium deficiency in hydroponics. Cultivation is performed using a hydroponic solution containing a very small amount of potassium in the late cultivation period of low potassium leafy vegetables, thereby keeping the potassium content low at the time of harvest and also allowing the leafy vegetables to be stably harvested at high yield without causing potassium deficiency.

Provided is a method for interplanting grape and Polygonatum kingianum in a photovoltaic (PV) power plant. The method includes: building a grapevine traction frame which is higher in south and lower in north in a space formed by a plurality of PV modules in the PV power plant, the grapevine traction frame includes a plurality of uprights, a plurality of traction crossbars, a plurality of supporting bars and a wire mesh; making a grape ridge below the south of each PV module and planting grape seedlings; maintaining two branches for each of the grape seedlings in the same year of grape planting, and pulling the two branches along the traction crossbar located in south; pulling branches grown out of arm bud points southwards onto the wire mesh in the next year of grape planting; sowing and ploughing a green manure, making planting beds in a shade and planting Polygonatum kingianum.

There is disclosed a combined net house and indoor farming system comprising a net covering the net house while allowing sunlight to pass through; and a plurality of photovoltaic (PV); wherein the plurality of PV panels simultaneously shades the net house and supplies energy to the indoor farming system. The plurality of PV panels cover a maximum of 50% of the net house.

An ecological restoration method for seawater back-flowing farmlands in a tropical region includes the following steps: performing soil ridging on a seawater back-flowing saline-alkalized land by using a whole-mulching double-ridge model thereof, a ridge body that has been ridged is a trapezoidal structure, and perpendicular to a direction of a coastline; planting a salt-tolerant plant on ridges, and planting Acanthus ilicifolius in furrows. Salts on the ridges are rinsed into the furrows by means of natural precipitation and irrigation; the Acanthus ilicifolius that have been planted in the furrows excretes redundant salts by using salt glands; the salt-tolerant plant and the Acanthus ilicifolius are harvested to effectively remove salts, thereby achieving an effect of reducing salts in soil by a dual-function of the ridges and the furrows.

An ecological restoration method for seawater back-flowing farmlands in a tropical region includes the following steps: performing soil ridging on a seawater back-flowing saline-alkalized land by using a whole-mulching double-ridge model thereof, a ridge body that has been ridged is a trapezoidal structure, and perpendicular to a direction of a coastline; planting a salt-tolerant plant on ridges, and planting Acanthus ilicifolius in furrows. Salts on the ridges are rinsed into the furrows by means of natural precipitation and irrigation; the Acanthus ilicifolius that have been planted in the furrows excretes redundant salts by using salt glands; the salt-tolerant plant and the Acanthus ilicifolius are harvested to effectively remove salts, thereby achieving an effect of reducing salts in soil by a dual-function of the ridges and the furrows.