The sustainability of global seafood supply to meet increasing demand is facing several challenges, including increasing consumption levels due to a growing human population, fisheries resources overexploitation, and climate change.
According to a new UBC study, the supply of farmed seafood such as salmon and mussels is projected to drop.
Ocean-farmed seafood or mariculture is often seen as a panacea to the problems of depleted stocks of wild fish and growing human demand, and is expected to grow substantially in the coming years, says lead author Dr. Muhammed Oyinlola (he/him), a postdoctoral research fellow at the Institute for the Oceans and Fisheries (IOF). But the new modeling study highlights the industry is as vulnerable to the effects of climate change as any other.
“If we continue to burn fossil fuels at our current rate, the amount of seafood such as fish or mussels able to be farmed sustainably will increase by only eight percent by 2050, and decline by 16 percent by 2090.”
If we consider low emission scenarios, then mariculture is projected to grow by about 17 percent by the mid-21st century and by about 33 percent by the end of the century, relative to the 2000s.
The model takes into account many factors, including changing ocean temperatures, suitable mariculture areas in the future, and the supply of fishmeal and fish oil. It examined approximately 70 percent of the world’s mariculture production as of 2015, focusing on Exclusive Economic Zones, where most of the world’s seafood farming occurs.
Climate change will affect mariculture production differently depending on where farms are in the world and what they produce, says Dr. Oyinlola. The hardest-hit regions in the high-emissions scenario— Norway, Myanmar, Bangladesh, the Netherlands, and China—could see their mariculture production decline by as much as 40 to 90 percent.
“Some regions produce more bivalves, such as mussels, oysters and clams, and in these regions, the impact is smaller,” Dr. Oyinlola said. “In regions that produce more finfish, such as salmon, the impact will be high due to reduction in the supply of fishmeal and fish oil.”
Under current carbon emission rates, finfish farming, such as salmon, is projected to decrease globally by three percent by 2050 and 14 percent by 2090. Bivalve farming is projected to increase by 2050 and decrease by 2090 under both climate scenarios.
Vegetarian fish: feeding fish soybeans
The study also found that substituting fishmeal and fish oil for plant-based foods such as soybeans could help alleviate the effects of climate change for fish farms.
When a quarter of the fish food was substituted with alternatives, under a low emissions scenario, mariculture production was projected to increase by 25 percent by 2050 and 31 percent by 2090.
With no change to current emissions, when a quarter of the fish food was substituted with alternatives, mariculture production was projected to increase by 15 percent by 2050 and four percent by 2090. These percentages increased when half the food was substituted in both climate scenarios.
“This study highlights the need to diversify mariculture development from the current focus on fish,” said senior author Dr. William Cheung (he/him), IOF professor and director. Climate-adapted mariculture would include species that are not dependent on fishmeal and fish oil, such as shellfish or algae, or those that can utilize non-fish-based feed. “Farming these species generally helps to reduce exposure of seafood farming to climate hazards.”
While there is enthusiasm about ocean mariculture helping increase seafood production, the study shows that if humans don’t relieve climate change, such enthusiasm will be tempered, says Dr. Cheung. “Climate change affects everything, including aspects of seafood farming we’ve not previously considered. We need to act, and quickly, to mitigate climate change rather than rely on one solution to solve all our seafood production problems.”
- Muhammed A. Oyinlola, et al., Projecting global mariculture production and adaptation pathways under climate change, Global Change Biology DOI: 10.1111/gcb.15991