The present invention relates to a method for utilizing fine-particle peat, in particular to a method for improving the stability of planting substrates.

The present invention relates to a method for utilizing fine-particle peat, in particular to a method for improving the stability of planting substrates.

The element is intended to be placed in a receptacle for the cultivation of at least one plant, and includes:

a substantially solid body including a substrate adapted to enable said plant to develop;

at least one seed of said plant disposed on the body in at least one seed receiving area;

a layer for holding the seed(s) in said receiving area, comprising a dried mineral powder.

The holding layer results from drying a deposition of a holding composition including a mineral powder suspended in water.

In various exemplary embodiments, a seed mat for insertion into an apparatus for growing plants is provided, wherein the seed mat includes a carrier substrate and seeds, wherein the seeds are fixed on the carrier substrate by means of an adhesive. Furthermore, a method for producing a seed mat in various exemplary embodiments may include: applying an adhesive on a carrier substrate; applying seeds on the carrier substrate provided with the adhesive; and fixing the seeds by the adhesive on the carrier substrate.

In various exemplary embodiments, a seed mat for insertion into an apparatus for growing plants is provided, wherein the seed mat includes a carrier substrate and seeds, wherein the seeds are fixed on the carrier substrate by means of an adhesive. Furthermore, a method for producing a seed mat in various exemplary embodiments may include: applying an adhesive on a carrier substrate; applying seeds on the carrier substrate provided with the adhesive; and fixing the seeds by the adhesive on the carrier substrate.

The mycelial foam contains macroscopic void spaces that are formed by filler elements, such as agar beads, that are incorporated in the mycelial matrix during growth of the matrix and are removed from the matrix after growth in a non-destructive manner, such as by heating. The foam may be made of pure mycelium or may be a composite biomaterial.

The mycelial foam contains macroscopic void spaces that are formed by filler elements, such as agar beads, that are incorporated in the mycelial matrix during growth of the matrix and are removed from the matrix after growth in a non-destructive manner, such as by heating. The foam may be made of pure mycelium or may be a composite biomaterial.

A plant growth media composition, articles made therefrom, and methods of making and using the same are described. The plant growth media composition includes a combination of one or more plant growth substrate materials and an additive such as cellulose fibers, clay, carrageenan, alginate, chitosan, or combinations thereof.

A horticulture tray including a plurality of growing cells each configured to accommodate a stabilized growth plug therein. A support peak of each cell is configured to protrude into a center of the stabilized growth plug and force soil of the stabilized growth plug outward and away from the support peak. A sidewall of each cell is angled to force soil of the stabilized growth plug inward and away from the sidewall. The support peak and the sidewall force soil of the stabilized growth plug together between the support peak and the sidewall to compact the soil to form a soil bridge that extends between the support peak and the sidewall, and prevents soil from passing through the growing cell.

A multiple cell horticulture propagation tray arranged in rows of star-shaped cells forming a substantially rectangular shaped tray having the cells formed therein, combined with inserted cylindrically shaped growing media plugs comprising primarily of peat moss with an amount of biochar, and enveloped to retain moisture within the growing media.