A system can be installed in a cabinet for growing plants. The system has a divider. The divider hermetically separates a plant space of the cabinet from a control space of the cabinet. The divider has a plant side, a control side, and electro-magnetic radiation (EMR) emitters, mounted on the plant side of the divider. The EMR emitters are adapted to EMR frequencies primarily at or near visible light. There is a filtered vent in the divider. The filtered vent has an air filter, a fan for pulling air through the filtered vent, and a microprocessor. The microprocessor controls the fan and the EMR emitters.

A system can be installed in a cabinet for growing plants. The system has a divider. The divider hermetically separates a plant space of the cabinet from a control space of the cabinet. The divider has a plant side, a control side, and electro-magnetic radiation (EMR) emitters, mounted on the plant side of the divider. The EMR emitters are adapted to EMR frequencies primarily at or near visible light. There is a filtered vent in the divider. The filtered vent has an air filter, a fan for pulling air through the filtered vent, and a microprocessor. The microprocessor controls the fan and the EMR emitters.

A combined power conversion and carbon capture and recycling subsystem including a fossil fueled oxidation unit, a physical adsorbent CO2 capture medium, rotor, motor, heater, CO2 compressor, diffuser and water storage tank. Exhaust gas from fossil fuel oxidation is scrubbed of CO2 via passage across a physical adsorbent and then released from the adsorbent via fuel oxidation waste heat. High CO2 concentration scrubber exhaust air is then compressed and fed to a diffuser which facilitates dissociation of the CO2 into water where it is temporarily stored for use in watering plants. Carbon from fossil fuel is recycled back into the environment and permanently stored as biomass by natural means of photosynthesis.

A combined power conversion and carbon capture and recycling subsystem including a fossil fueled oxidation unit, a physical adsorbent CO2 capture medium, rotor, motor, heater, CO2 compressor, diffuser and water storage tank. Exhaust gas from fossil fuel oxidation is scrubbed of CO2 via passage across a physical adsorbent and then released from the adsorbent via fuel oxidation waste heat. High CO2 concentration scrubber exhaust air is then compressed and fed to a diffuser which facilitates dissociation of the CO2 into water where it is temporarily stored for use in watering plants. Carbon from fossil fuel is recycled back into the environment and permanently stored as biomass by natural means of photosynthesis.

The combined grow rack and ventilation system for plants comprises one or more grow racks that each define local aerated cells each corresponding to one shelf of the grow racks, for the plants to grow therein. A grow rack ventilation system is provided that includes a cell gas supply duct at each the aerated cell, with an inlet for connection to a gas supply and an outlet, to supply gas to the aerated cell. The ventilation system also includes a cell gas evacuation duct at each the aerated cell, with an inlet disposed near the aerated cell for evacuating gas from the aerated cell, and a discharge outlet. The system also includes a positive pressure device providing positive pressure in each the cell gas supply duct, and a negative pressure device providing negative pressure in each the cell gas evacuation duct. Local forced gas flows are formed distinctly at each the aerated cells for both supplying and evacuating gas locally at each the aerated cell.

A bioreactor includes a first compartment designed to retain seaweed sporophytes, a second compartment in fluid communication with the first compartment that includes one or more settlement surfaces, and a first porous barrier between the first and second compartments that allows the seaweed spores to pass from the first compartment to the second compartment, and systems comprising the bioreactor. Also provided herein are methods of culturing seaweed, for example, using a bioreactor provided herein.

A bioreactor includes a first compartment designed to retain seaweed sporophytes, a second compartment in fluid communication with the first compartment that includes one or more settlement surfaces, and a first porous barrier between the first and second compartments that allows the seaweed spores to pass from the first compartment to the second compartment, and systems comprising the bioreactor. Also provided herein are methods of culturing seaweed, for example, using a bioreactor provided herein.

A control space operating system. The system includes a control space with one or more data source zones and a control space manager. The control space manager can collect data and control different variables across different data source zones in order to determine optimal policies and conditions for data source growth and generation.

A control space operating system. The system includes a control space with one or more data source zones and a control space manager. The control space manager can collect data and control different variables across different data source zones in order to determine optimal policies and conditions for data source growth and generation.

A growspace automation system and method. The system includes a grow space with localization structures and a mobile robot. The mobile robot comprises sensors, a mobility mechanism, and a plurality of mobility modules. The mobile robot is configured to automate growspace processes, such as transport, watering, sensing, or cleaning.