Location: Cool and Cold Water Aquaculture Research2013 Annual Report
1a. Objectives (from AD-416):
Recirculating aquaculture systems (RAS) provide control of water quality and temperature to optimize fish production and health, provide barriers that prevent escape of fish and entry of pathogens, contain and remediate waste flows to curtail environmental impact, and minimize water use. RAS can allow a commercial fish farm to locate where power, feed, or oxygen is relatively inexpensive, where environmental impact can be minimized, and/or adjacent to their primary markets. However, RAS are dependent on relatively larger energy inputs than traditional flow-through or net-pen systems. Thus, strategies are required for reducing energy consumption and improving waste disposal, which both are major factors in a fish farm’s overall life cycle assessment. In addition, production techniques must be developed to improve biosecurity and reduce stress and disease outbreaks in fish cultured in closed containment systems. This work will integrate research and technology advancements, and resolve current and emerging constraints to the expanded use of land-based, closed containment systems for the production of safe and nutritious salmon and other cool- and cold-water species. Objective 1: Identify criteria to optimize the performance, health, welfare and consumer value of Atlantic salmon and other salmonids grown to food-size in intensive, land-based, closed-containment systems. Objective 2: Improve the effectiveness, energy efficiency, and economics of water reuse and waste treatment technologies and practices. This will include developing technologies to minimize waste and reclaim water, protein, and/or energy to improve the economic and environmental sustainability of closed-containment systems. Objective 3: Conduct production trials of fish and feeds developed through ARS collaborations.
1b. Approach (from AD-416):
Research at The Conservation Fund’s Freshwater Institute focuses on developing and improving technologies to enhance the sustainability and reduce the environmental impact of the modern fish farming industry. To this end, the proposed projects listed in this plan will continue our work in pioneering land-based, closed containment water recirculation systems that are biosecure, have an easily controlled rearing environment, produce healthy and optimally performing fish, and produce manageable effluent for significant reduction in waste discharge. Specifically, our proposed research will investigate, among other things, the biological and economic feasibility of raising Atlantic salmon to market size in freshwater recirculation systems (as opposed to coastal net-pens); the potential for raising rainbow trout in semi-closed or closed water recirculation systems to further reduce the amount of influent water and point source discharge required for these systems; the health and welfare of salmon and trout in relation to dissolved oxygen and carbon dioxide levels, swimming speed in circular tanks, soy-based feeds, and water ozonation in low-exchange systems; and the potential for greater energy efficiency in water recirculation systems through improved low-lift pumping and gas transfer processes. In addition, our experimental systems will continue to serve as field testing sites for alternative-protein feeds and for salmon and trout strains selected through genetic improvement programs at other USDA facilities. The investigations proposed in this plan will build on the findings of previous years of USDA-funded research to develop a sustainable, environmentally responsible, and economically viable aquaculture industry in the United States.
3. Progress Report:
The overall goal of this project is to develop and improve technologies that enhance the sustainability and reduce the environmental impacts of the modern fish farming industry. Progress was made in several areas. Research on Atlantic salmon performance, health, and welfare, plus system water quality, was completed in replicated water recirculating systems that were operated at either high makeup water (2.5% flow exchange) or low makeup water (0.25% flow exchange) flushing rates. This work has provided valuable information to producers intent on rearing Atlantic salmon in closed-containment systems up to market size in fresh water. The economics and sustainability of large-scale land-based closed-containment systems for Atlantic salmon growout were investigated. A preliminary life cycle assessment was completed to quantify greenhouse gas and energy use impacts of the model facility and the highlights from the economic model were published in a report. We also collaborated with researchers at SINTEF (Norway) to determine differences in fixed and variable costs and environmental impacts of land-based and net pen salmon production systems based on a standardized evaluation. Experiments were completed to identify the cost effectiveness of anoxic fluidized-sand biological reactors using heterotrophic denitrification to convert nitrate in the water to benign dinitrogen gas. Organic carbon that is necessary to drive denitrification was supplied by organic acids that were recovered from the supernatant exiting the gravity thickening tanks used to dewater biosolid waste. Findings will provide lower cost yet effective technology to remove nitrate nitrogen from effluent waters of land-based closed-containment systems. Selected Atlantic salmon (NCWMAC, Franklin, ME) germplasm resources, one group diploid and the other triploid, were cultured from parr to post-smolt size in a growout trial within a commercial-scale intensive water recirculating systems.