A high throughput system for sorting a plurality of different small object types into a plurality of cells of a plurality of small object cassettes is provided. The system comprises: at least one small object cassette having a plurality of small object cells; an automated conveyor system for transporting the cassette(s) from a loading location to a unloading location on the conveyor system; at least one cassette filling station disposed over the conveyor system such that the conveyor system extends under a small object distribution subsystem of each respective cassette filling station; and a computer based central control system structured and operable to control various operations of the conveyor system and each cassette filling station.

A high throughput system for sorting a plurality of different small object types into a plurality of cells of a plurality of small object cassettes is provided. The system comprises: at least one small object cassette having a plurality of small object cells; an automated conveyor system for transporting the cassette(s) from a loading location to a unloading location on the conveyor system; at least one cassette filling station disposed over the conveyor system such that the conveyor system extends under a small object distribution subsystem of each respective cassette filling station; and a computer based central control system structured and operable to control various operations of the conveyor system and each cassette filling station.

A seedling-package forming system includes a first conveyor including a first track and a first sheet arranged on the first track. A second conveyor is located at a downstream position and includes a second track and a second sheet arranged to lie on the second track. The second track is configured to transport the second sheet toward the first sheet. The first sheet and the second sheet are packed around a plurality of seedlings to form a seedling package.

Provided herein are systems and methods for the automation of seed planting and analysis comprising automated planting of the seeds, germination, and analysis. The methods generally comprise conveying containers containing seeds to an automated seed planting station, wherein each container includes a machine-readable tag, planting at least some of the seeds in the container onto respective planting trays, wherein each planting tray includes a machine-readable tag, allowing the seeds to germinate, and analyzing the germinated seeds. The systems generally comprise a seed planting system and a planting verification and correction system. Also provided herein are backlit templates comprising a light source and a power interface configured to connect to a power source to power the light source.

Provided herein are systems and methods for the automation of seed planting and analysis comprising automated planting of the seeds, germination, and analysis. The methods generally comprise conveying containers containing seeds to an automated seed planting station, wherein each container includes a machine-readable tag, planting at least some of the seeds in the container onto respective planting trays, wherein each planting tray includes a machine-readable tag, allowing the seeds to germinate, and analyzing the germinated seeds. The systems generally comprise a seed planting system and a planting verification and correction system. Also provided herein are backlit templates comprising a light source and a power interface configured to connect to a power source to power the light source.

A planting structure includes a water filtering bag, a plurality of hanging ears mounted on an outer face of the water filtering bag, and a plurality of planting sources placed in the water filtering bag. The water filtering bag is made of permeable material with a permeation effect. The water filtering bag has an interior provided with a receiving space. The planting sources are received in the receiving space of the water filtering bag. Thus, the planting structure is directly hung on a cup by the hanging ears, so that the user plants and takes out the planting sources at any time according to the practical requirement.

A bottle for adaptive reuse includes a bottle body defining an open interior configured to hold a substance therein. A chamber is formed into the bottle body at least in part by a wall between the open interior and the chamber. The chamber is selectively isolated from the open interior of the bottle. A sealing plate at least partially defines the chamber and an outer surface of the bottle. A threaded structure secures the sealing plate to the bottle body.

A bottle for adaptive reuse includes a bottle body defining an open interior configured to hold a substance therein. A chamber is formed into the bottle body at least in part by a wall between the open interior and the chamber. The chamber is selectively isolated from the open interior of the bottle. A sealing plate at least partially defines the chamber and an outer surface of the bottle. A threaded structure secures the sealing plate to the bottle body.

An erosion control slurry is disclosed. The slurry includes water and a substrate, wherein the substrate comprises: mulch at a weight of x; bentonite clay at a weight of about 0.25x to about 0.495x; and cellulosic water dispersible polymer or starch at a weight of about 0.0025x to about 0.125x. Also disclosed are a substrate that can be mixed with liquid to provide an erosion control slurry, and methods of controlling or reducing erosion.

An erosion control slurry is disclosed. The slurry includes water and a substrate, wherein the substrate comprises: mulch at a weight of x; bentonite clay at a weight of about 0.25x to about 0.495x; and cellulosic water dispersible polymer or starch at a weight of about 0.0025x to about 0.125x. Also disclosed are a substrate that can be mixed with liquid to provide an erosion control slurry, and methods of controlling or reducing erosion.