Oceans are warming becoming more acidic, and coral reefs are rapidly declining primarily due to anthropogenic global warming (climate change). Methods must be found to preserve as many of the 3000 species of soft corals as possible before they are gone. Maintaining biodiversity on coral reefs is essential to a balanced healthy reef. Since the chances of a political solution to reducing greenhouses gases are very unlikely, steps must be taken now to collect, preserve, and propagate as many marine reef organisms as possible including soft corals. Propagation methods of stony corals are well known, but soft corals are far more difficult to propagate due to their lack of a stony skeleton. This invention presents three methods for high volume, efficient, and inexpensive propagation of soft corals Alcyonacea (Octocorallia) and Corallimorpharia. Two methods use cubes in an eggcrate matrix, and the third involves propagating soft corals on glass plates.

Oceans are warming becoming more acidic, and coral reefs are rapidly declining primarily due to anthropogenic global warming (climate change). Methods must be found to preserve as many of the 3000 species of soft corals as possible before they are gone. Maintaining biodiversity on coral reefs is essential to a balanced healthy reef. Since the chances of a political solution to reducing greenhouses gases are very unlikely, steps must be taken now to collect, preserve, and propagate as many marine reef organisms as possible including soft corals. Propagation methods of stony corals are well known, but soft corals are far more difficult to propagate due to their lack of a stony skeleton. This invention presents three methods for high volume, efficient, and inexpensive propagation of soft corals Alcyonacea (Octocorallia) and Corallimorpharia. Two methods use cubes in an eggcrate matrix, and the third involves propagating soft corals on glass plates.

A coral ring mount device and method for the propagative culture of sessile benthic marine organisms (for example, stony corals) employing either a ring, washer or threaded nut or similar as a propagule mount upon which the coral is set in order to attach, grow and overgrow within a coral nursery system. In the preferred embodiment of the invention, once the coral is grown onto the ring mount and to its requisite size and condition, the ring mount becomes the washer through which passes a screw to secure the ring and coral to the seafloor.

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.

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 coral ring mount device and method for the propagative culture of sessile benthic marine organisms (for example, stony corals) employing either a ring, washer or threaded nut or similar as a propagule mount upon which the coral is set in order to attach, grow and overgrow within a coral nursery system. In the preferred embodiment of the invention, once the coral is grown onto the ring mount and to its requisite size and condition, the ring mount becomes the washer through which passes a screw to secure the ring and coral to the seafloor.

A rapidly deployable underwater coral cultivation system comprising a tensioned propagule support line or rod, and a propagule-encircling loop for attachment thereto, wherein the propagules' tissues and skeleton overgrow the line/rod. Multiple propagules of a single genetic clone on a line/rod may fuse into a single linear coral colony, whereby the natural structural and anti-fouling attributes of the target organism provide structural rigidity to the system and high survivorship of the live material in nursery culture. A preferred embodiment may provide a low to no maintenance protocol soon after deployment thereby allowing for set and forget through self-planting endpoints. In some embodiments, a vertical arrangement provides full leverage advantage to the support buoy as growth increases (coral) weight. In some embodiments, the vertically-oriented single genetic clone facilitates gamete capture for facilitated spawning in coral (ecosystem) enhancement and restoration.