A method of growing shellfish is disclosed. The method comprises obtaining a support tray (I) with recesses (7) where at least some of the recesses (7) incorporate means adapted to create a deliberately formed alphanumeric, written or pictorial mark on the shellfish as it grows. Shellfish spat are attached to at least some of the recesses (7) and the tray (I) is placed in water so that the spat grow into substantially mature shellfish within the recesses (7). The spat each grow generally in the shape of their respective recess (7) so that the mark is created on the shellfish as it grows.

The present invention relates to a method of aquaculture of at least one farmed organism, such as fish, shrimp or any organism suitable for farming in an aquatic environment. There is provided a method of aquaculture of at least one farmed organism, the method comprising steps: (i) providing an aquatic environment comprising at least one farmed organism, phytoplankton and bacteria; (ii) providing at least one phytoplankton nutrient and at least one bacteria nutrient during a first predetermined period, allowing phytoplankton and bacteria to grow in a first predetermined phytoplankton:bacteria ratio of more than 1; (iii) providing at least one phytoplankton nutrient and at least one bacteria nutrient during a second predetermined period, allowing phytoplankton and bacteria to grow in a second predetermined phytoplankton:bacteria ratio, wherein the second predetermined phytoplankton:bacteria ratio is lower than the first predetermined phytoplankton:bacteria ratio; and (iv) providing at least one phytoplankton nutrient and at least one bacteria nutrient during a third predetermined period, allowing phytoplankton and bacteria to grow in a third predetermined phytoplankton:bacteria ratio, wherein the third predetermined phytoplankton:bacteria ratio is lower than the second predetermined phytoplankton:bacteria ratio, thereby allowing the at least one farmed organism to grow.

The present invention relates to a method of aquaculture of at least one farmed organism, such as fish, shrimp or any organism suitable for farming in an aquatic environment. There is provided a method of aquaculture of at least one farmed organism, the method comprising steps: (i) providing an aquatic environment comprising at least one farmed organism, phytoplankton and bacteria; (ii) providing at least one phytoplankton nutrient and at least one bacteria nutrient during a first predetermined period, allowing phytoplankton and bacteria to grow in a first predetermined phytoplankton:bacteria ratio of more than 1; (iii) providing at least one phytoplankton nutrient and at least one bacteria nutrient during a second predetermined period, allowing phytoplankton and bacteria to grow in a second predetermined phytoplankton:bacteria ratio, wherein the second predetermined phytoplankton:bacteria ratio is lower than the first predetermined phytoplankton:bacteria ratio; and (iv) providing at least one phytoplankton nutrient and at least one bacteria nutrient during a third predetermined period, allowing phytoplankton and bacteria to grow in a third predetermined phytoplankton:bacteria ratio, wherein the third predetermined phytoplankton:bacteria ratio is lower than the second predetermined phytoplankton:bacteria ratio, thereby allowing the at least one farmed organism to grow.

A steel structure cage for marine crustacean aquaculture and integration thereof into a vertical fish-crustacean aquaculture system are disclosed. The steel structure cage includes a steel frame, top, side and bottom net systems, a ballast tank system, and steel grooves. The steel frame includes internal and external steel frames. The steel grooves are fixed on upper and lower ends of the internal steel frame. Edges of the top and bottom net systems are respectively fixed into the corresponding steel grooves. The side net is welded on the internal steel frame. The ballast tank system is arranged between the internal and external steel frames. A HDPE cage is moored to the steel structure cage to form a vertical aquaculture system. Whereby, an ideal culturing environment for marine crustaceans is given and the objective of vertical aquaculture culturing fish at top water layers and culturing prawns (crabs or cowries) at bottom water layers can be fulfilled.

A technology for enhancing ingestion efficiency of algae-eating fish and shellfish is provided. A method of determining feed for algae-eating fish and shellfish includes: feeding algae-eating fish or shellfish with a plurality of samples, the samples each containing algal cells and being different from each other in a stage of growth or division of the algal cells; and selecting, as a feed for giving to the algae-eating fish or shellfish, the algal cells whose stage of growth or division is the same as that of the algal cells contained in the sample most preferably eaten by the algae-eating fish or shellfish.

A technology for enhancing ingestion efficiency of algae-eating fish and shellfish is provided. A method of determining feed for algae-eating fish and shellfish includes: feeding algae-eating fish or shellfish with a plurality of samples, the samples each containing algal cells and being different from each other in a stage of growth or division of the algal cells; and selecting, as a feed for giving to the algae-eating fish or shellfish, the algal cells whose stage of growth or division is the same as that of the algal cells contained in the sample most preferably eaten by the algae-eating fish or shellfish.

The present invention includes an apparatus configured for aquaculture, and more specifically for kelp growth and kelp farming. The apparatus includes a vertical central mast connected to horizontal buoyancy bars that are also connected to six vertical vertex struts surrounding the central mast. Buoyancy bars further connect adjacent vertex struts, such that the top profile of the apparatus is a hexagon. The apparatus is able to be connected to and share elements of other similar apparatuses, allowing for ease of aggregation of the apparatuses for scalable farming. The central mast is optionally configured to integrate a wind turbine, which is optionally able to power water pumps in the six vertex struts, which serve to transport water upward around the apparatus for more efficient carbon sequestration by the apparatus.

The present invention includes an apparatus configured for aquaculture, and more specifically for kelp growth and kelp farming. The apparatus includes a vertical central mast connected to horizontal buoyancy bars that are also connected to six vertical vertex struts surrounding the central mast. Buoyancy bars further connect adjacent vertex struts, such that the top profile of the apparatus is a hexagon. The apparatus is able to be connected to and share elements of other similar apparatuses, allowing for ease of aggregation of the apparatuses for scalable farming. The central mast is optionally configured to integrate a wind turbine, which is optionally able to power water pumps in the six vertex struts, which serve to transport water upward around the apparatus for more efficient carbon sequestration by the apparatus.

An aquaculture system can include an aquafarm with one or more aquatic pods of aquatic organisms and a remote device to manage the aquafarm. An aquatic pod may be associated with an aquatic structure with a buoyancy system and a control device to automatically perform daily farming functions. The aquatic structure may include an enclosure to hold the aquatic organisms. The control device may be configured to use a smart buoyancy assistant to control the buoyancy system and to determine the farming task to perform in response to environmental stimuli. The remote device can receive data representing crop metrics, harvest results, and sensor data. The remote device can aggregate data from multiple aquatic pods and correlate the data to generate aquaculture models to improve the harvest results. The remote device can generate overview and maintenance reports for the aquafarm.

An aquaculture system can include an aquafarm with one or more aquatic pods of aquatic organisms and a remote device to manage the aquafarm. An aquatic pod may be associated with an aquatic structure with a buoyancy system and a control device to automatically perform daily farming functions. The aquatic structure may include an enclosure to hold the aquatic organisms. The control device may be configured to use a smart buoyancy assistant to control the buoyancy system and to determine the farming task to perform in response to environmental stimuli. The remote device can receive data representing crop metrics, harvest results, and sensor data. The remote device can aggregate data from multiple aquatic pods and correlate the data to generate aquaculture models to improve the harvest results. The remote device can generate overview and maintenance reports for the aquafarm.