Examples of the disclosure provide for an apparatus for actively promoting marine life. The apparatus includes a datacenter implemented in a body of water and coupled to a network, a pressure vessel that houses the datacenter, and one or more components coupled to the pressure vessel and adapted to actively promote reef life and sustain a surrounding ecosystem.

An object of the present invention is to provide oysters which are highly safe and not contaminated with microorganisms including viruses and bacteria, the oysters moreover being fresh and having high nutritional value, and being available throughout the year in the same state as oysters from the in-season period. Provided is a method for cultivating oysters on land, the method including growing oyster larvae into adult shellfish in seawater containing deep-sea water in a water tank through feeding microalgae cultured in seawater containing deep-sea water to the oyster larvae. Specifically, provided is a method for cultivating oysters on land, the method including growing oysters in a suspension system including seedling collectors suspended vertically or horizontally on ropes by allowing deep-sea water to continuously flow through the system without stagnation or repeatedly allowing deep-sea water to stagnate and continuously flow through the system without stagnation at a given interval at a seawater temperature of 10 C. to 30 C. for 5 months to 18 months.

A fish processing device and method of use, the device including: a channel; a sensor located within or adjacent to the channel; a barrier, the barrier to assist in preventing a fish passing through the channel; and a control system, wherein the control system controls the barrier in response to an output of the sensor. The method including the steps of: detecting that a fish is incorrectly orientated in a channel; and controlling a barrier to assist in preventing the fish from passing through the channel.

A fish processing device and method of use, the device including: a channel; a sensor located within or adjacent to the channel; a barrier, the barrier to assist in preventing a fish passing through the channel; and a control system, wherein the control system controls the barrier in response to an output of the sensor. The method including the steps of: detecting that a fish is incorrectly orientated in a channel; and controlling a barrier to assist in preventing the fish from passing through the channel.

Disclosed is a protector for a clip and line used to suspend aquaculture baskets or like equipment in water. In particular, the protector provides a sacrificial element between the clip and the line that is cheap to manufacture and easy to replace. While an application of the present invention is in oyster cultivation, it could equally well be applied to any process involving the line suspension of an article in water.

A method for taking fish up from a body of water comprising the steps of providing a duct (14) having a lower open end below the water surface and an upper open end arranged at a floating working platform (5) above sea level; introducing water into the duct (14) from the upper open end to give a water stream from the upper open end of the duct to the lower open end of the duct; and allowing the fish to swim up in the duct against the water stream therein. The incoming water is directed to flow into the duct, and the fish is separated from the flowing by means of a grating (16) inclining upwards from the top end of the duct to a separation plate (17) arranged above the water level in the duct. A device for taking up fish, using the mentioned method is also described.

An autonomous submersible structure includes a cage for protecting cargo contained within a volume of the cage, two or more independently operated propellers, and a raised platform. The raised platform includes a plurality of sensors and computers that detect at least one of: water quality, water pressure, or objects in the vicinity of the cage. The raised platform includes a navigating system that controls a direction of travel of the cage based on feedback provided by the plurality of sensors and computers, and a power generator that provides power to the sensors, the navigating system, and the feeding mechanism. The autonomous submersible structure includes a ballast for counterbalancing the weight of the raised platform, wherein the navigating system controls the two or more independently operated propellers to alter the direction of travel of the cage, and wherein the raised platform is environmentally sealed and a portion of the raised platform is positioned above water level.

Provided is a method for rearing Artemias in a feeding water tank, wherein a feed containing a mollusk-derived feed is poured into the feeding water tank. Provided is a feed for Artemia that contains a mollusk-derived feed. Provided is an Artemia which satisfies at least one of the following requirements at 6 days of age: body width being greater than 0.183 mm; body height being greater than 0.179 mm; and volume greater than 0.099 mm.sup.3.

This cephalopod breeding method is a method for breeding cephalopod larvae in a rearing tank having a water changing means. The method includes a water-changing period during which the ratio of water changed by the water-changing means per day is 200% or more relative to the quantity of water in the rearing tank in a floating breeding period of the cephalopod larvae.

A cephalopod breeding method, which is for breeding cephalopod larvae in a breeding water tank, comprises, during the floating breeding period of the cephalopod larvae, forming a high concentration area where the salinity concentration is higher compared to seawater at the bottom of the breeding water tank and, after the passage of a predetermined time from the formation of the high concentration area, removing the high concentration area.