A foliage shredder that can shred inputted foliage matter into uniform sized particles without pulverizing the inputted foliage matter includes a housing, a shredding axle, a motor, a stand, a digital timer, a power cord, and a lid. The shredding axle is concentrically positioned within a cylindrical compartment of the housing and rotatably coupled to a rotor of the motor. A stator of the motor is externally connected to the housing and electrically connected to the power cord through the digital timer. The lid is terminally attached to the housing thus closing the cylindrical compartment. The cylindrical compartment functions as a container unit for the inputted foliage as the electrically powered shredding axle shreds the inputted foliage into uniform sized particles.

A flowering plant growing system utilizes a flowering plant growth assembly that enables the limbs of a flowering plant to be retained and supported along a bud platform to spread the growth out in a planar configuration. This type of growth arrangement may stimulate the plant to produce buds that are distributed across the bud platform and may grow up from the bud platform toward a cover. The height of the bud platform and cover may be adjustable as they are secured to vertical supports by retainers.

A flowering plant growing system utilizes a flowering plant growth assembly that enables the limbs of a flowering plant to be retained and supported along a bud platform to spread the growth out in a planar configuration. This type of growth arrangement may stimulate the plant to produce buds that are distributed across the bud platform and may grow up from the bud platform toward a cover. The height of the bud platform and cover may be adjustable as they are secured to vertical supports by retainers.

The present invention provides a growing support structure for use in planting crop and ornamental plants which supports the growth of the plant and may improve fruit production. The tool is a cage structure through which the plant grows, propping up the shoots of the plant and supporting the fruit, flowers, and/or other anatomical structures, keeping them from contacting the ground, thereby preventing rot. The cage structure also allows the plant to still receive the benefit of sunlight, as the cage allows the passage of sunlight.

The present invention provides a growing support structure for use in planting crop and ornamental plants which supports the growth of the plant and may improve fruit production. The tool is a cage structure through which the plant grows, propping up the shoots of the plant and supporting the fruit, flowers, and/or other anatomical structures, keeping them from contacting the ground, thereby preventing rot. The cage structure also allows the plant to still receive the benefit of sunlight, as the cage allows the passage of sunlight.

A method for increasing floral yield of a flowering plant includes positioning the plant between side lights at the onset of a flowering stage of the plant, such that the plant is flanked by the side lights. The method also includes irradiating lateral sides of the flowering plant along the total height via the side lights with light in a predetermined red spectrum range for a duration of the flowering stage, such that at least 80 percent of the light has a wavelength of between 580 nm and 780 nm. The plant may be positioned between first and second sets of equally-spaced elongated side lights on respective first and second lateral sides of the plant. Supplemental lighting devices may be attached to the plant, with an interior of the plant irradiated with the red spectrum light for the duration of the flowering stage using the lighting devices.

A method for increasing floral yield of a flowering plant includes positioning the plant between side lights at the onset of a flowering stage of the plant, such that the plant is flanked by the side lights. The method also includes irradiating lateral sides of the flowering plant along the total height via the side lights with light in a predetermined red spectrum range for a duration of the flowering stage, such that at least 80 percent of the light has a wavelength of between 580 nm and 780 nm. The plant may be positioned between first and second sets of equally-spaced elongated side lights on respective first and second lateral sides of the plant. Supplemental lighting devices may be attached to the plant, with an interior of the plant irradiated with the red spectrum light for the duration of the flowering stage using the lighting devices.

The invention relates to novel nitrification inhibitors of formula I, which are substituted thiazolidine compounds. Moreover, the invention relates to the use of compounds of formula (I) as nitrification inhibitors, i.e. for reducing nitrification, as well as agrochemical mixtures and compositions comprising the nitrification inhibitors of formula (I).

This invention relates to methods and materials for providing a benefit to a plant by associating the plant with a complex endophyte comprising a host fungus further comprising a component bacterium, including benefits to a plant derived from a seed or other plant element treated with a complex endophyte. For example, this invention provides purified complex endophytes, purified complex endophyte components such as bacteria or fungi, synthetic combinations comprising said complex endophytes and/or components, and methods of making and using the same.

The present invention relates to the field of soilless cultivation, in particular to a method for cultivating Mesembryanthemum crystallinum. The method involves the following steps: sowing; accelerating germination; growing seedlings; transplanting; separating seedlings; harvesting. In this method, Mesembryanthemum crystallinum is cultivated using a nutrient solution and under continuous indoor lighting; as a result, the Mesembryanthemum crystallinum has a shortened life cycle, no flowering period, and a long harvesting period. Edible salt is added to the nutrient solution at a specific ratio, which further promotes the growth of Mesembryanthemum crystallinum and changes its taste. Meanwhile, the nutrient solution of Mesembryanthemum crystallinum has a high EC, which promotes the growth of Mesembryanthemum crystallinum. In this method, the step of separating seedlings is carried out at a reasonable time to ensure the quality of Mesembryanthemum crystallinum growth, and to fully utilize light energy and growth space.