The present invention relates to a system and method for cultivating an seaweed, preferably Sarcothalia crispata, including releasing spores from seaweed reproductive tissue, inoculating a substrate with spores, germinating the spores and growing seaweed from the germinated spores. The invention also relates to a harvested batch of seaweed having a lambda carrageenan content of at least about 80 wt. % based on mass of all carrageenans and wherein the mass of seaweed is at least 100 kg, more preferably at least 500 kg and most preferably at least 1000 kg.

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.

The present description relates to cryo-sprouts that have been germinated, grown and shipped in the same container. Seeds are placed on a membrane in the container with sufficient water. The container with the seeds is incubated at a pathogen antagonistic temperature during the growth phase. The pathogen antagonistic temperature is preferably between about 35? F. and about 45? F. The cryo-sprouts grown according to these methods have reduced numbers of pathogenic organisms, are greener and have an extended shelf-life.

Seeds are subject to ultrasonic treatment to enhance and reduce the time for the germination process. In particular to this invention, the seeds are treated ultrasonically while the seeds are in a dry state. A dry sonification process for a dry seed and apparatus produces a sonically-treated dry seed having an enhanced germination characteristic and providing an enhanced growth characteristic to a plant resulting therefrom. The sonification process includes subjecting the dry seed to be sonically treated to sound energy at a frequency and energy density and applying for a sufficient time such that the sonically-treated dry seed has an enhanced germination characteristic and a plant resulting from the sonically-treated dry seed has an enhanced growth characteristic. The ultrasonic treatment can include applying the ultrasonic sound energy in different alternating waveforms, or in a batch or continuous process, with continuous flow through a helical flow path.

Embodiments herein disclosed relate to a computer-controlled germination system built around a rotating vessel within which a germinating process takes place. The system includes automatable controls over air flow, water flow, temperature, and vessel rotation.

Embodiments herein disclosed relate to a computer-controlled germination system built around a rotating vessel within which a germinating process takes place. The system includes automatable controls over air flow, water flow, temperature, and vessel rotation.

The present invention provides methods for testing seed germination and predicting seed emergence in stressful field conditions, such as cold and flooding stress. Cold Soak Test and ultra-drying methods are provided herein. The methods find use in the development of corn breeding technologies and germplasm selection to evaluate and develop new hybrids that can produce stable stands under stressful field conditions.

The present invention provides methods for testing seed germination and predicting seed emergence in stressful field conditions, such as cold and flooding stress. Cold Soak Test and ultra-drying methods are provided herein. The methods find use in the development of corn breeding technologies and germplasm selection to evaluate and develop new hybrids that can produce stable stands under stressful field conditions.

A germination facility includes a seedling growing system configured to grow a plurality of seedlings; and a seedling sorting device configured to receive spatially variable planting data regarding a planting area for planting the seedlings; receive seedling data regarding the plurality of seedlings; and arrange the plurality of seedlings in a planting container based on the seedling data and on the planting data.

A germination facility includes a seedling growing system configured to grow a plurality of seedlings; and a seedling sorting device configured to receive spatially variable planting data regarding a planting area for planting the seedlings; receive seedling data regarding the plurality of seedlings; and arrange the plurality of seedlings in a planting container based on the seedling data and on the planting data.