A degradable aroma product with seeds wrapped therein includes plant seeds and growth carriers coated or mixed with plant nutrients and aromatizers. The degradable aroma product may be in the form of an aroma card with the growth carriers being made of paper pulp, or alternatively, in the form of an aroma sachet with the plant seeds and the growth carriers or the aroma card wrapped in a degradable packaging bag. When the degradable aroma product has been used over a period of time and no longer produces fragrance, it can be directly buried in soil without forming any pollutant and accordingly, meets the requirement of plastic and waste reduction. Further, with the plant nutrients, the plant seeds can grow into trees, flowers or fruits more easily to enable sustainable development of healthy circle of life (i.e. the product design concept of cradle-to-cradle), carbon reduction and environmental protection.

A seedling planter is configured to plant a plurality of seedlings in ground. The seedling planter includes a vehicle body, a seedling-storage unit, and a seedling-distribution unit. The seedlings are held together in the form of a seedling package that is stored within the seedling-storage unit. The seedling-distribution unit is configured to separate each seedling from the seedling package and plant each seedling in the ground as the vehicle body travels across the ground. A method includes forming the seedling package.

The present invention provides a smart plant cultivation device and a smart plant cultivation system which, by using an Internet of things (IoT) technology, can automatically configure a cultivation environment according to a variety of plants, automatically perform zoning control of a light source module, and monitor and record a cultivation process of a plant through a user device.

Systems and methods of restoring a lake including dredging, island creation, water treatment, real estate development, computer modeling of environmental conditions, wave height reduction, sediment removal and encapsulation, bathymetry contouring, littoral zone restoration, plant restoration, and/or fish restoration.

Crops, for example microgreens, may be aeroponically grown from seed on substrates. The substrates may be seeded with the substrates in a horizontal position, and then arranged vertically for germination and further growth. A gelling material in solution, with the gelling material for example a gellum, may be applied to the substrates, while in the horizontal position, so that the seeds are retained on the substrates when the substrates are moved to a vertical position.

Methods and systems, including computer programs encoded on computer-storage media, for controlling a system for growing seaweed are described. Some implementations of a method include forming a substrate loop inoculated with seaweed spores; arranging the substrate loop about a pulley; submerging the substrate loop to grow the seaweed; determining, using a seaweed farm controller, that the seaweed has grown to a pre-determined size; and based on the determination that the seaweed has grown to a pre-determined size: providing instructions to the pulley to feed a section of the substrate loop to a harvesting unit; providing instructions to the harvesting unit to separate the seaweed attached to the section of the substrate loop; providing instructions to a cleaning unit to clean the section of the substrate loop that is freed from seaweed; and providing instructions to a seeding unit to inoculate the cleaned section of substrate loop with seaweed spores.

Systems and methods of restoring a lake including dredging, island creation, water treatment, real estate development, computer modeling of environmental conditions, wave height reduction, sediment removal and encapsulation, bathymetry contouring, littoral zone restoration, plant restoration, and/or fish restoration.

Disclosed is a biomechanical measuring technical method for maize seed radicle and coleorhiza separation, which is characterized by comprising the following operations: (1) seed sample preparation; (2) anterior tissue cutting; (3) radicle and coleorhiza separation; (4) coleorhiza sample acquisition; (5) coleorhiza sample fixation; (6) puncture force measurement; (7) information storage and analysis. The operation (3) includes the development of a maize radicle and coleorhiza separation device, and the operation (5) includes the development of a maize coleorhiza sample carrier. The present disclosure has the beneficial effects of providing direct biomechanical evidence for the research on the coleorhiza weakening regulation and control mechanism of the maize seed germination, and simultaneously providing reference for measuring the coleorhiza weakening biological force of the gramineous plant seeds.

A canola seed sample crusher features a frame, and a drum rotatably carried on the frame and having an array of seed pockets on an outer periphery thereof. The seed pockets are sized and shaped to receive individual canola seeds respectively therein. A pathway is arranged to receive a length of adhesive tape and guide same over the seed pockets in the outer periphery of the drum during rotation thereof to adhesively collect the sample of canola seeds from the seed pockets onto the adhesive tape. A crushing mechanism is carried on the frame and operatively installed at a position along the pathway to crush the sample of canola seeds collected on the adhesive tape during passage of the tap through the crushing mechanism.

The system includes a pre-fabricated garden seedsheet, with seeds and soil embedded in water-soluble pods within a weed barrier fabric. Each water-soluble pod is fabricated from dissolvable material, which are affixed together to form cavities in which seeds and soil are applied. The pods are then affixed to the weed barrier matrix in an arrangement dictated by the plant algorithm. Upon contact with water, the pods rapidly dissolve, thereby beginning the germination process in which the seeds sprout and emerge through the aligned openings in the weed barrier fabric. The selection of plants and their physical arrangement within each seedsheet may be determined by a software-driven plant algorithm that extrapolates plant characteristics, environmental requirements, and companion benefits. The algorithm may be used both on the customer-facing software program, as well as the in-house design process to create pre-designed seed sheets.