With traditional, inshore net-pens likely to be phased out over time, the development of a combination of closed-containment and offshore aquaculture systems is required to ensure the salmon farming sector remains viable in the long-term.
Nofima’s Åsa Espmark, who is director of CtrlAQUA, a centre for research-driven innovation in closed-containment farming systems, and Sintef’s Hans Bjelland, director of Exposed – are behind the research of an initiative looking into farming in high energy locations
“The reason why we are researching closed containment facilities is that the traditional method of open-net fish farming alone will not be sustainable in the future. The fish farming industry must find alternative ways to farm salmon. Closed-containment aquaculture (CCA) will make it possible to farm salmon practically without salmon lice and escaped fish, as there will be a physical barrier between the fish and the sea so the lice cannot enter and fish cannot escape. We are now conducting research to find ways to make salmon thrive in such facilities,” says Espmark.
21 partners are working with CtrlAQUA, from the research, fish farming and supply industry sectors. This collaboration is set to produce an off-the-shelf product of CCA solutions by 2023. CtrlAQUA researchers are committed to working on solutions that are land-based facilities and semi-closed facilities at sea for production of salmon of up to 1 kg.
“CtrlAQUA stops there, as it is before the weight reaches one kilogram that we can do anything significant to strengthen the robustness, health and wellbeing of the fish. The rest is, to put it simply, basically a transport stage for the fish to grow bigger,” says Espmark.
“As a salmon is approaching the target weight of five kilograms, it requires far more space than when it is small. With closed-containment farming, the total Norwegian salmon production would require enormous land areas. It would also be very energy intensive and technologically challenging to operate an onshore fish farm with pumps and salt-water recycling, as salmon should preferably live in salt water as it matures.
“I believe it will have a significant positive impact on the environment if we can reduce the amount of time the salmon spends in the sea by allowing it to spend more of its life in land-based facilities than it currently does,” she adds.
Hans Bjelland of Sintef, director of Exposed, supports Espmark and CtrlAQUA working collaboratively through exploration of opportunities for the future of aquaculture technology.
“The reasons for working with developing fish farming operations in exposed locations are that there is plenty of space; stable, good water conditions; and greater distance between each fish farming facility, which reduces the infection pressure. At the same time, ocean currents carry away fish faeces and uneaten feed,” Bjelland says.
“If we are able to let salmon grow big on land before it’s transferred to sea, we can reduce the time spent at sea from the current 16-18 months down to 10 months, which means we can also avoid the two most severe winter months. Every third salmon that escapes does so during bad weather – and bad weather is more prevalent in winter,” he adds.
Salmon that are to be transported to offshore facilities far from land must be able to endure hours of strong currents and more waves than the salmon placed in net pens in more sheltered environments.
“In the Exposed SFI [centre for research-based innovation] we are doing a great deal of research on swimming capacity and behaviour. The SFIs are complementing each other in this regard. Whereas researchers in CtrlAQUA are researching health and production efficiency in fish farming in order to produce smolt that can survive the transition to the sea, we also need even more robust smolt that can survive the transition to a more demanding open-sea environment,” says Bjelland.
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