Researchers there are working on the basis of a hypothesis that an extended phase in RAS facilities on land will improve fish growth and welfare in the sea.
In addition, longer time in land facilities will result in a shorter production time in the sea, which is favourable in terms of reducing the risk of sea lice and escapes.
Researchers have previously shown that large smolts that have lived in good environmental conditions on land, have significantly lower mortality in the sea than fish who are transferred to the sea when small.
But the results of new trials with the transfer of fish of varying sizes to the sea show that biggest isn’t necessarily always best.
“The question is whether it is most important that the time the salmon spend in the sea is minimised, or whether overall production is as efficient as possible,” says Trine Ytrestøyl, project manager of the trials, which are carried out at CtrlAQUA SFI.
Trials with light, brackish water and different sizes
The trials started with 30 gram salmon juveniles in tanks with recycled water at Nofima’s research facility in Sunndalsøra. The control group were smoltified by light control (winter signal) and were transferred to the sea as 100 gram smolt in August. The other groups were either exposed to 24-hour light for the entire land phase, or given a winter signal with a short day for six weeks, like the control fish. Both light regimes were tested in both freshwater and brackish water, and the fish were transferred to the sea at around 200 grams in October or 600 grams in December. The fish were slaughtered at the end of November the following year, when they were around four and a half kilos.
The fish grew differently
The most efficient production regime in the recycling facility was brackish water combined with 24-hour lighting for the entire land phase. The positive effect on growth by not giving the fish a winter signal was greatest when the fish were 200 grams, but still noticeable when transferring the 600 gram fish.
The fish with the best overall growth through life were, however, the fish that were transferred to sea at 100 grams after undergoing traditional smoltification. The fish that were 600 grams at the time of transfer had the poorest growth. The latter ate little during the first three weeks in the sea, and had poorer growth in the summer. Although there were growth differences between the groups, all groups had good growth compared to the performance in commercial farming, with growth factors (TGC) between 2.9-3.3 in the sea phase.
What was perhaps most surprising, report the researchers, was that the fish in all of the production regimes endured the transfer to seawater, even though not all were smoltified in the traditional way by light control. Survival in the sea phase was 93%, and there were no differences between the groups.
“It appears that salmon are quite flexible with regard to time of transfer to seawater, and this provides opportunities for several different production strategies,” Ytrestøyl says.
What about sexual maturation?
Early sexual maturation among male fish is a problem in land-based salmon production. Sexual maturation is affected by light regime and temperature that control the growth rate.
“We saw a clear tendency towards more sexual maturation among male fish in the recycling facility when they had reached 600 grams, compared to when the fish were 100 and 200 grams. But we found no clear correlation between light regime or salinity in the recycling facility and sexual maturation,” Ytrestøyl says. “In the sea phase we found very few sexually mature male fish. Perhaps a greater proportion of the male fish would have become sexually mature if they had remained in recirculating facility until slaughter, but this was not tested in this trial.”
There are several good production regimes
The researchers’ conclusion is that several production strategies in recirculating facility may be used for the production of young salmon. The trial showed that the most effective production regimes in the recycling facility on land don’t necessarily result in the best growth in the sea phase. However, for a fish farmer, it may be of greatest importance to minimise the time in the sea.
Because the fish had different production times in the land phase, they were transferred at different times in the autumn, at different temperatures and day lengths.
“These are factors that affect the growth patterns of salmon, and we should therefore be cautious before drawing conclusions on which production regimes in recirculating facility that are best with regard to growth in the sea. However, based on the results of this trial, a traditional smolt of 100 grams was the most effective strategy,” Ytrestøyl says.
It remains to be seen whether the same results would have been achieved if the fish had been transferred to sea in the spring with rising sea temperatures and longer days.
Ytrestøyl nevertheless emphasises that in order to reduce the risk of escape and sea lice, it is sensible to reduce the time the salmon spend in the sea. This illustrates that there are many unanswered questions with regard to how large post-smolts should be produced, and how the season at the time of transfer affects performance in the sea phase. Research will continue into these issues at CtrlAQUA.