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A submergible wave energy converter and method for using the same are described. Such a wave energy converter may be used for deep water operations. In one embodiment, the wave energy converter apparatus comprises an absorber having a body with an upper surface and a bottom surface and at least one power take-off (PTO) unit coupled to the absorber and configured to displace movement of the absorber body relative to a reference, where the power take-off unit is operable to perform motion energy conversion based on displacement of the absorber body relative to the reference in response to wave excitation, and where the power take-off unit is operable to return the absorber body from a displaced position to a predefined equilibrium position and to provide a force acting on the absorber body for energy extraction.

The objective of the project is to advance the Technology Readiness Level (TRL) of the Wave Energy Converter (WEC) developed by CalWave Wave Power Technologies Inc (CalWave) through advanced numerical simulations, dynamic hardware tests, and ultimately a scaled open water demonstration deployment while continuing to exceed DOE's target ACE threshold of 3m/M$. The outcomes of Budget Period 1 will be a detailed design of the scaled demonstration unit and bench testing of the critical hardware components.

Of the known toxins produced by cyanobacteria, microcystins and nodularins are the most significant threat to human and animal health. Knock-out studies have confirmed that microcystins are produced nonribosomally by a multienzyme complex consisting of peptide synthetases, polyketide synthases, and tailoring enzymes. Gene clusters for microcystin biosynthesis have been identified and sequenced in the distantly related cyanobacterial genera Microcystis, Planktothrix, and Anabaena. Homologous genes have been detected in a nodularin-producing Nodularia strain. Subsequently, microcystin biosynthesis (mcy) genes have been used to establish molecular techniques for the detection of toxigenic cyanobacteria in laboratory and field studies. mcy genes of unknown origin can be assigned to the producing species. Techniques are currently being developed for the quantification of mcy genes in field populations. These initial genetic investigations pave the way for a molecular monitoring of microcystin- and nodularin-producing cyanobacteria and for studying the dynamics of toxic cyanobacteria in lakes. Furthermore, microcystin-deficient mutants have significantly increased our knowledge about the impact of the toxins on Microcystis-Daphnia interactions. The experience gained on microcystin biosynthesis genes will be valuable for a risk assessment of microcystin in the environment and for future water management and lake-restoration strategies.