A device for treating seeds includes a container with an internal space for containing a plurality of seeds, air humidity adjusting means for adjusting relative humidity of the air supplied to the internal space, moisture amount information obtaining means for obtaining moisture amount information about a total amount of moisture in the plurality of seeds, and control means for controlling the air humidity adjusting means on the basis of the moisture amount information obtained by the moisture amount information obtaining means during a treatment period of a treatment process for treating the plurality of seeds so that the relative humidity of the air present in the internal space is such that the total amount of moisture in the plurality of seeds follows a predetermined moisture amount development line, along which the total amount of moisture in the plurality of seeds must run during the treatment period of the treatment process.

The present invention discloses a CIELAB color space-based quantitative testing and analysis method for rice seed viability, and the method comprises removing husks on surfaces of rice seeds, soaking and imbibing the rice seeds without the husks removed, staining the rice seeds by using a TTC staining solution, and longitudinally cutting the rice seeds along embryos; converting the longitudinal section image of the rice seed from an RGB color space to a CIELAB color space, and calculating L value, a value and b value per unit area of the rice embryo as a staining intensity per unit area, and converting the staining intensity into a rice seed viability score according to a pre-established conversion model of the staining intensity and the rice seed viability score. According to the present invention, a reference result can be provided for the rapid, accurate and objective evaluation of the seed viability.

Disclosed herein is a high growth, high density, closed environment growing system and methods thereof. A method of accelerating plant cell growth in a growing system may include adjusting the lighting in accordance with an identified plant growth stage.

Methods for preserving viability of plant tissues such as plant embryos are provided herein. Also included are methods for storing genomic DNA and/or molecular marker assay materials in an oil bilayer as part of a high-throughput molecular characterization system. Moreover, plant embryos may be treated while in an oil matrix. The treatment may include chromosome doubling, Agrobacterium-mediated transformation, or herbicide selection as part of an embryo rescue process.

A seed activation system includes a shattering layer applied to an outer surface of a seed. The shattering layer forms a water-resistant coating around the seed that prevents the seed from germinating. An activation mechanism for transmitting electromagnetic energy is provided such that the shattering layer is compromised to break the water-resistant coating. The seed is then able to receive water and germinate. A seed activation method includes applying a shattering layer to an outer surface of a seed. The shattering layer forms a water-resistant coating around the seed that prevents the seed from germinating. The method further includes planting the seed in a soil, selecting an activation time, and activating the seed at the activation time by transmitting electromagnetic energy into the soil such that the shattering layer is compromised thereby breaking the water-resistant coating. The seed is then able to receive water for germinating.

A seed activation system includes a shattering layer applied to an outer surface of a seed. The shattering layer forms a water-resistant coating around the seed that prevents the seed from germinating. An activation mechanism for transmitting electromagnetic energy is provided such that the shattering layer is compromised to break the water-resistant coating. The seed is then able to receive water and germinate. A seed activation method includes applying a shattering layer to an outer surface of a seed. The shattering layer forms a water-resistant coating around the seed that prevents the seed from germinating. The method further includes planting the seed in a soil, selecting an activation time, and activating the seed at the activation time by transmitting electromagnetic energy into the soil such that the shattering layer is compromised thereby breaking the water-resistant coating. The seed is then able to receive water for germinating.

A method of increasing the probability and rate of seed germination, increasing vegetative biomass, and increasing water uptake in seeds, in which a seed is introduced to an effective concentration of carbon nanomaterial. The effective concentration of carbon nanomaterial is 10-200 g/mL.

A method of increasing the probability and rate of seed germination, increasing vegetative biomass, and increasing water uptake in seeds, in which a seed is introduced to an effective concentration of carbon nanomaterial. The effective concentration of carbon nanomaterial is 10-200 g/mL.

An automated system for sampling seeds generally includes an automated sampling station having a sampler configured to remove material from a seed while protecting germination viability of the seed, a seed conveyor configured to receive the seed from out of the sampling station after the material is removed from the seed, and a sample conveyor configured to receive the material removed from the seed. The sample conveyor is configured to locate the material removed from the seed in a sample container, and the seed conveyor is configured to locate the seed from which the material is removed in a seed container so as to facilitate a one-to-one correspondence between the seed and the material removed from the seed.

Disclosed herein is a high growth, high density, closed environment growing system and methods thereof. A method of accelerating plant cell growth in a growing system may include adjusting the lighting in accordance with an identified plant growth stage.