Tag Archives: fisheries management

Open-Ocean Farming

image from https://www.innovasea.com/

Ocean Farm 1is the first of six experimental fish farms ordered by SalMar, a Norwegian firm, at a total cost of $300 million. InnovaSea, an American firm, makes large open-ocean aquaculture nets called SeaStations, which are currently used off the coast of Panama and Hawaii, but Ocean Farm 1 is “by far the largest open-ocean fish farm in the world,” says Thor Hukkelas, who leads research and development on aquaculture at Kongsberg Maritime, a Norwegian engineering company. Mr Hukkelas’s team provided Ocean Farm 1’s sensor system: 12 echo sounders mounted on the bottom of the frame, high-definition cameras dangled into the water at different depths, oxygen sensors and movable, submerged feeding tubes.

Fish farming plays an increasingly central role in the provision of sufficient amounts of protein to Earth’s population. People eat more fish globally than beef, and farmed fish account for almost half of that amount  Many wild fisheries are already at or past their sustainable capacity, so efforts to make fish farming more productive are vital.

Ocean Farm 1 aims to automate what is an expensive and difficult business, and to solve two key problems that occur in near-shore aquaculture: that there is not enough space and that it is too polluting. The excrement from millions of salmon can easily foul up Norway’s fjords, and their shallow, relatively still water is a breeding ground for sea lice. In the open ocean the water is deeper and better oxygenated. The currents are stronger and so better able to sweep away excrement.

Near-shore farms normally spread feed on the water’s surface and allow it to sink, but Ocean Farm 1 has 16 valves at varying depths, through which feed can be pushed. By putting it farther down in the cage it is able to keep the salmon in deeper water. The salmon are fine with this. The sea lice, which like the shallows, are not.

All of this means the number of fish can be increased. The Norwegian government wants to triple its aquaculture production by 2030 and quintuple it by 2050. “Scaling up of traditional aquaculture is not going to reach these high-growth ambitions,” says Mr Hukkelas.

Kongsberg is gathering data from all the sensors on the farm to build a machine-learning model, called SimSalma, which learns the behaviour of the salmon in order to optimise their feeding. Currently, human operators on the structure decide when and where to feed the fish by examining the data. By 2019 Kongsberg plans to have automated this, pushing feed at optimum times and places and reducing human involvement. The success and expansion of such projects would represent a major step towards maintaining global fish stocks.

Net gains: Open-ocean fish farming is becoming easier, Economist,  Mar. 10, 2018.

The Survival of Red-Listed Bluefin

Japanese call bluefin tuna “the king of fish”. They eat about 40,000 tonnes of it a year—80% of the global catch. Demand is also growing rapidly elsewhere. Yet Pacific bluefin stocks are down by 97% from their peak in the early 1960s, according to a recent report from the International Scientific Committee, an intergovernmental panel of experts. (Japan disputes its findings.) In some places, fishing is three times the sustainable level, the committee says.

Aquaculture might seem to offer a way out of this impasse. But the bluefin is hard to breed in captivity. In the open sea, it can roam for thousands of miles and grow to over 400kg. It is highly sensitive to light, temperature and noise. Early attempts to farm it fizzled, but Kindai University persisted long after an initial research grant from the government ran out in the early 1970s. In 2002, funding itself from sales of other fish, it managed to rear adult tuna from eggs for the first time, rather than simply fattening up juveniles caught at sea. Now the chefs in Ginza can have a tuna zapped with an electric prod and yanked out of the university’s tanks on demand.

However, just 1% of the bluefin the university rears survive to adulthood. “We expect this to improve but it will take time,” predicts Shukei Masuma, the director of its Aquaculture Research Institute. Worse, the tuna gobble up lots of wild mackerel and squid. Scientists have experimented with soy-based meal and other alternatives. A company in south-western Japan said this month that it had managed to raise tuna using feed made of fishmeal, but it is costly and the fish are slow to thrive. Using wild fish for feed makes bluefin farming unsustainable, says Atsushi Ishii of Tohoku University. He sees aquaculture as a distraction from the thorny task of managing fisheries properly.

This debate is slowly seeping into the public consciousness. In 2014 the media made much of the decision of the International Union for Conservation of Nature, a conservation body, to put bluefin tuna on its “red list” of species threatened with extinction.

Excerpts from The Japanese Addiction to Tuna: Breeding Bluefin, Economist, Sept 24, 2016

Vaquita and Totoaba–endangered fish as delicacy

fish bladder factory californa

The most recent estimate puts the remaining numbers of vaquita, a porpoise found only in the waters of the Sea of Cortés, Mexico, at just 60, down from 100 two years ago…. The vaquita has been a victim of the shrimp and totoaba fisheries, showing up as bycatch in gillnets.

The totoaba is also an endangered species but its swim bladder is a delicacy in China, selling for as much as US $5,000 per kilogram in the U.S. and a great deal more in China. The matter has been taken up by Agriculture Secretary José Calzada Rovirosa with Chinese officials in an effort to stop the illegal consumption of the bladders.  Vaquitas are not only being killed by totoaba fishing. When illegal fishermen are pursued by the Mexican Navy, they often cut their nets and set them adrift, becoming an additional threat to the porpoise.

Removing these “ghost nets” will be one of the steps taken before the implementation of an assisted breeding program, said marine mammal expert Lorenzo Rojas Bracho from the National Institute of Ecology and Climate Change.

There are doubts about the feasibility of a breeding program as well as concerns about the risk. “We have no idea whether it is feasible to find, capture and maintain vaquitas in captivity much less whether they will reproduce,” said vaquita expert Barbara Taylor of the U.S. National Oceanic and Atmospheric Administration.

Excerpt from Assisted breeding for endangered vaquita?, Mexco News Daily, June 28, 2016

Justice 4 Fish

 image from News VietNamNet

Hundreds of people have held a rare protest in Vietnam against the unexplained mass death of fish on the country’s central coast. Vast numbers of dead fish have appeared across some 200km (125 miles) of coastline since early April. A government investigation has so far found no links to a steel plant owned by Taiwanese firm Formosa Plastics.But many of the demonstrators in Hanoi blamed the company, and carried placards saying “Formosa Out”. Other signs read “Formosa destroying the environment is a crime” and “Who poisoned the central region’s waters?”  Environment Minister Tran Hong Ha said the die-off was “a very huge and serious environment disaster” and admitted that the government had been slow to react.He said Formosa Plastics had been ordered to dig up an illegal waste pipe at its plant.

Fishermen along the affected coastline are banned from selling their stocks, but seafood industry officials said exports, that bring in $6.6b a year, would not be affected.

Excerpt from Vietnam protest over mystery fish deaths, BBC, May 1, 2016

Regulation of Deep-Sea Fishing by Depth: the scientific facts

setting a trawl. image from wikipedia

A study published in 2009 suggested that in all but the deepest of their waters—those with a seabed closer than 1,500 metres to the surface—yields had dropped by 70% over 25 years. Even in the abyss below that depth, the fall was 20%. To try to stem this decline the European Union, which regulates fishing in much of the area, is proposing to limit the depth at which trawling can take place. This would, in effect, create a marine reservoir below that level, a form of protection additional to the system of species-specific quotas that already exists. The question is where the line below which trawl-gear is forbidden should be drawn. And, until now, there have been few scientific data to inform that decision.
This has just changed, however, with the timely publication, inCurrent Biology, of a study by Jo Clarke of Glasgow University and Francis Neat of Marine Scotland Science, a government agency. Their work suggests that the appropriate cut-off would be at a depth of 600 metres—below which the ecological damage caused by trawling increases substantially.

Ms Clarke and Dr Neat derive their conclusion from data collected between 1978 and 2013 by Marine Scotland Science and the Universities of Aberdeen and St Andrews. These data record species caught, and also the depths of the trawls that caught them, which ranged from 250 to 1,500 metres.

The researchers note that biodiversity increases with depth. On average, an extra 18 fish species show up with each 100-metre increase. Many of these, though, are of little commercial value. Such so-called by-catch gets thrown back, but by then most of it is dead. And that, particularly because deep-sea species tend to grow more slowly than those which live near the surface, and have lower fecundity rates, can have profound effects on ocean ecology.  Trawls at 300 metres, Ms Clarke and Dr Neat found, have a ratio of catch to by-catch (in terms of weight) of five to one. At 600 metres the ratio is around three to one. At 800 metres, though, it is ten to nine; at 1,000 metres one to one; and at 1,200 metres, one to two.

Based on these findings, Ms Clarke and Dr Neat suggest that a trawl limit of 600 metres would be a suitable compromise between commercial reality and ecological necessity.

Excerpts from Fisheries: Drawing the line, Economist, Sept.  5, 2015, at 80

Damaged Fish For Sale


The global fish-price index of the UN’s Food and Agricultural Organisation (FAO) hit a record high in May 2013.  High oil prices, which increase the cost of fishing and transportation, also add to the price of putting fish on the table.  Not all fish are created equal, however. There are two types of fish production: “capture” (or wild) and “aquaculture” (or farmed). And they seem to be on different trajectories. Fish such as tuna, the majority of which is caught wild, saw much bigger price increases than salmon, which are easier to farm. Overall, the FAO’s price index for wild fish nearly doubled between 1990 and 2012, whereas the one for farmed fish rose by only a fifth. What explains this big difference?

The amount of wild fish captured globally has barely changed in the past two decades. The ceiling, of about 90m tonnes a year, seems to have been reached at the end of the 1980s. Overfishing is one reason, as is the limited room for productivity growth, particularly if consumers want high quality.

Patrice Guillotreau of the University of Nantes tells the story of a fleet in France that decided to trawl, rather than line-catch, its tuna. It brought more back to shore, but the fish were damaged. It could not be sold as high-value fillets and was only good for canning. The old ways of catching fish are still best if you want the highest profits, says Mr Guillotreau.

In contrast, the farmed-fish industry continues to make productivity improvements. Fish farms have found crafty ways to use lower quantities of fishmeal as feed. In the early days of aquaculture, it could take up to ten pounds of wild fish to produce one pound of salmon. Now the number is down to five. That may still be an inefficient use of protein, but the ratio is set to improve further. Fish farms have also become more energy-efficient, meaning that they are less affected by higher energy prices. And they have learned how to handle diseases better, reducing the quantity of fish that ends up being unsellable.  As a result of all these improvements, the global production of farmed fish, measured in tonnes, now exceeds the production of beef. Output is likely to continue growing: the FAO estimates that by 2020 it will reach six times its 1990 level.

This growth will further shake up the markets for fish. The farmed kind is expected to dominate the market for medium-value produce. Suppliers of wild fish, for their part, must slither into niche markets. At the low-value end wild sardine is a crucial input for farmed fish and is in abundant supply. More than a third of the total marine catch in 2010 was used for the production of fishmeal and fish oil.  But more money may be made serving the captains of industry rather than industry itself. Sapmer, a French fishing company, recently discontinued its canned-tuna production, instead concentrating on catching tuna for sushi and sashimi for the top end of the market.

Frank Asche of the University of Stavanger, who helped to devise the FAO fish-price index, sees parallels with the divergence between farmed meat and wild game. As the supply of wild fish declines relative to farmed fish, it will become a luxury commodity, he explains. “In 20 years’ time people will think of wild fish like we now think of venison.”

The price of fish: Different scales, Economist, Aug. 10, 2013, at 64

Resuscitating Collapsed Fisheries: catch shares

For American fish, this is a good time to be alive. On May 14th, 2012 the National Oceanic and Atmospheric Administration (NOAA) reported that a record six federal fisheries returned to health last year (pdf). After a decade of similar progress, 86% of America’s roughly 250 federally monitored commercial fish stocks were not subject to overfishing; 79% were considered healthy…

In the late 1980s cod fisheries in the Gulf of Maine and Georges Bank collapsed. This led to efforts to improve the fishery act, in 1996 and 2006, which forced the eight regional bodies that manage federal fisheries to introduce science-based quotas and ten-year recovery programmes for depleted fisheries. The recent recovery of species, including New England scallops, mid-Atlantic bluefish and summer flounder and Pacific lingcod, is the result. This signals another truth: given a break, the marine environment can often replenish itself spectacularly.

America’s fisheries are probably now managed almost as well as the world’s best, in Norway, Iceland, New Zealand and Australia. Yet there is plenty of room for improvement. State-run fisheries, which tend to be close to shore and dominated by small-scale and inefficient fishermen, are less well funded and well managed and much poorer for it. New England groundfish stocks, including cod, have also not recovered: they account for 13 of the remaining depleted populations. This appears to be partly the result of environmental change, climatic or cyclical.

And the politicians are still interfering. On May 9th the House passed legislation forbidding NOAA from developing an innovative means of apportioning fishing quotas, known as catch shares. These are long-term, aiming to give fishermen a stake in the future of their fisheries; market-based, since they can be traded; and, in practice, good for fish. Sadly, the two Republican congressmen behind the ban consider they have been designed “to destroy every aspect of American freedom under the guise of conservation”.

Fish stocks: Plenty more fish in the sea, Economist, May 26, 2012, at 32

Sustainable Fisheries: quotas and Peru

For decades anchovetas have been ground into fishmeal, of which Peru is the world’s top producer. They have suffered from rampant overfishing, whose effects are sometimes amplified by the disruptive El Niño and La Niña weather patterns. The annual catch peaked at 12m tonnes before the stock collapsed in 1972, taking years to recover.

Now Peru is trying to make better use of one of its prime resources, in two ways. The government has introduced a quota aimed at ensuring that 5m tonnes of anchoveta are left each year as spawning stock. Since 2009 this has been refined so that the overall quota (set at 4.1m tonnes this year for the first of the two fishing seasons) is divided up among the country’s 1,600 registered trawlers. Each boat’s quota is transferable; the aim is to have a smaller, more efficient fleet.

In January the minister of production, Jorge Villasante, ended the season with less than 35% of the quota caught because there were too many juveniles, he says. Management of the fishery has improved, concedes Patricia Majluf, a zoologist at Lima’s Cayetano Heredia University, but she says there is still not enough information about stocks to know whether it is sustainable.

At the same time, some in the fishing industry have realised that selling anchoveta as food for people, rather than as fertiliser or animal feed, is more profitable. Human consumption of anchoveta in Peru has risen from 10,000 tonnes in 2006 to 190,000 tonnes in 2010. Most of this is canned, like sardines.

One fishing company, Inversiones Prisco, has begun to produce salted and cured anchovy fillets. They are smaller than the prized Mediterranean or Cantabrian anchovy. But supply is far more abundant. Prisco is already the world’s “fifth or sixth” biggest exporter of anchovies, according to Hugo Vernal, its manager. It is investing $30m to double production.

Fishing in Peru, The Next Anchovy, Economist, May 7, 2011, at 41