Ocean acidification growing risk to west coast fishery, including crab and salmon, US studies show

The United States says acidification of the oceans means there is an already growing risk to the northwest coast fishery, including crab and salmon, according to studies released by the National Oceanic and Atmospheric Administration.

As more carbon dioxide is released into the atmosphere and absorbed by the oceans, the water is becoming more acidic and that affects many species, especially shellfish, dissolving the shells.

A NOAA study released today of environmental and economic risks to the Alaska fishery says:

Many of Alaska’s nutritionally and economically valuable marine fisheries are located in waters that are already experiencing ocean acidification, and will see more in the near future…. Communities in southeast and southwest Alaska face the highest risk from ocean acidification because they rely heavily on fisheries that are expected to be most affected by ocean acidification…

An earlier NOAA study, released in April, identified a long term threat to the salmon fishery as small ocean snails called pteropods which are a prime food source for pink salmon are already being affected by the acidification of the ocean.

Pteropod
This photograph from NOAA of a pteropod, important in the ocean diet of pink salmon, shows the first evidence of marine snails from the natural environment along the U.S. West Coast with signs that shells are dissolving. (NOAA)

NOAA says:

The term “ocean acidification” describes the process of ocean water becoming more acidic as a result of absorbing nearly a third of the carbon dioxide released into the atmosphere from human sources. This change in ocean chemistry is affecting marine life, particularly the ability of shellfish, corals and small creatures in the early stages of the food chain to build skeletons or shells.

Today’s NOAA study is the first published research by the Synthesis of Arctic Research (SOAR) program, which is supported by an US inter-agency agreement between NOAA’s Office of Oceanic and Atmospheric Research and the Bureau of Ocean Energy Management (BOEM) Alaska Region.

Canada’s Department of Fisheries and Oceans says it has ongoing studies on oceanic acidification including the role of petropods in the lifecycle of the salmon.

Des Nobles, President of Local #37 Fish [UFAWU-UNIFOR] told Northwest Coast Energy News that the fisheries union and other fisheries groups in Prince Rupert have asked both the Canadian federal and the BC provincial governments for action on ocean acidification. Nobles says so far those requests have been ignored,

Threat to crabs

The studies show that red king crab and tanner crab grow more slowly and don’t survive as well in more acidic waters. Alaska’s coastal waters are particularly vulnerable to ocean acidification because of cold water that can absorb more carbon dioxide and unique ocean circulation patterns which bring naturally acidic deep ocean waters to the surface.

“We went beyond the traditional approach of looking at dollars lost or species impacted; we know these fisheries are lifelines for native communities and what we’ve learned will help them adapt to a changing ocean environment,” said Jeremy Mathis, Ph.D., co-lead author of the study, an oceanographer at NOAA’s Pacific Marine Environmental Laboratory in Seattle, and the director of the University of Alaska Fairbanks School of Fisheries and Ocean Sciences Ocean Acidification Research Center.

As for Dungeness crab, Sarah Cooley,  a  co-author of the Alaska study, who was with the Woods Hole Oceanographic Institution at the time, told Northwest Coast Energy News, “The studies have not been done for Dungeness crab that have been done for king and tanner crab, that’s something we’re keenly aware of. There’s a big knowledge gap at this point.” She says NOAA may soon be looking at pilot study on Dungeness crab.

Healthy pteropod
A healthy pteropod collected during the U.S. West Coast survey cruise. (NOAA)

Risk to Salmon, Mackerel and Herring

In a 2011-2013 survey, a NOAA-led research team found the first evidence: “that acidity of continental shelf waters off the West Coast is dissolving the shells of tiny free-swimming marine snails, called pteropods, which provide food for pink salmon, mackerel and herring.”

The survey estimated that the percentage of pteropods along the west coast with dissolving shells due to ocean acidification had “doubled in the near shore habitat since the pre-industrial era and is on track to triple by 2050 when coastal waters become 70 percent more corrosive than in the pre-industrial era due to human-caused ocean acidification.”

That study documented the movement of corrosive waters onto the continental shelf from April to September during the upwelling season, when winds bring water rich in carbon dioxide up from depths of about 120 to  180 metres to the surface and onto the continental shelf.

“We haven’t done the extensive amount of studies yet on the young salmon fry,” Cooley said. “I would love to see those studies done. I think there is a real need for that information. Salmon are just so so important for the entire Pacific Northwest and up to Alaska.”

In Prince Rupert, Barb Faggetter, an independent oceanographer whose company Ocean Ecology has consulted for the fisherman’s union and NGOs, who was not part of the study, spoke generally about the threat of acidification to the region.

She is currently studying the impact of the proposed Liquified Natural Gas terminals that could be built at Prince Rupert near the Skeena River estuary. Faggetter said that acidification could affect the species eaten by juvenile salmon. “As young juveniles they eat a lot of zooplankton including crustaceans and shell fish larvae.”

She added, “Any of the shell fish in the fishery,  including probably things like sea urchins are all organisms that are susceptible to ocean acidification because of the loss of their capacity to actually incorporate calcium carbonate into their shells.”

Faggetter said her  studies have concentrated on potential habitat loss near Prince Rupert as a result of dredging and other activities for liquified natural gas development,  She adds that ocean acidification “has been a consideration that climate change will further worsen any potential damage that we’re currently looking at.”

Her studies of the Skeena estuary are concentrating on “rating” areas based on the food supply available to juvenile salmon, as well as predation and what habitat is available and the quality of that habitat to identify areas that “are most important for the juvenile salmon coming out of the Skeena River estuary and which are less important.”

She said that climate change and ocean acidification could impact the Skeena estuary and “probably reduce some of the environments that are currently good because they have a good food supply. If ocean acidification reduces that food supply that will no longer be good habitat for them” [juvenile salmon].

NOAA expediton
Bongo nets are deployed up to 200 meters deep to catch marine snails (pteropods), which are indicators of the progress of ocean acidification. The pteropod samples were collected during the U.S. West Coast survey cruises in 2011 and 2013. Unlike the US, Canada’s DFO is using models to track what’s happening to pteropods. (NOAA)

The  August 2011 NOAA survey of the pteropods was done at sea using “bongo nets” to retrieve the small snails at depths up to 200 metres. The research drew upon a West Coast survey by the NOAA Ocean Acidification Program in that was conducted on board the R/V Wecoma, owned by the National Science Foundation and operated by Oregon State University.

The DFO study, according to the agency website is “being examined in the context of model predictions.

Nina Bednarsek, Ph.D., of NOAA’s Pacific Marine Environmental Laboratory in Seattle, the lead author of the  April pteropod paper said, “Our findings are the first evidence that a large fraction of the West Coast pteropod population is being affected by ocean acidification.

“Dissolving coastal pteropod shells point to the need to study how acidification may be affecting the larger marine ecosystem. These near shore waters provide essential habitat to a great diversity of marine species, including many economically important fish that support coastal economies and provide us with food.”

Ecology and economy

Today’s study on the effects of acidification on the Alaska fishery study examined the potential effects on a state where the fishing industry supports over 100,000 jobs and generates more than $5 billion in annual revenue. Fishery-related tourism also brings in $300 million annually to the state.

Map of Alaska
A map of Alaska shows the economic and ecological risks to parts of the state from ocean acidification. (NOAA)

The study also shows that approximately 120,000 people or roughly 17 percent of Alaskans rely on subsistence fisheries for most, if not all of their dietary protein. The Alaska subsistence fishery is open to all residents of the state who need it, although a majority of those who participate in the subsistence fishery are Alaska’s First Nations. In that way it is somewhat parallel to Canada’s Food, Ceremonial and Social program for First Nations.

“Ocean acidification is not just an ecological problem—it’s an economic problem,” said Steve Colt, Ph.D., co-author of the study and an economist at the University of Alaska Anchorage. “The people of coastal Alaska, who have always looked to the sea for sustenance and prosperity, will be most affected. But all Alaskans need to understand how and where ocean acidification threatens our marine resources so that we can work together to address the challenges and maintain healthy and productive coastal communities.”

The Alaska study recommends that residents and stakeholders in vulnerable regions prepare for environmental challenge and develop response strategies that incorporate community values and needs.

“This research allows planners to think creatively about ways to help coastal communities withstand environmental change,” said Cooley, who is now science outreach manager at Ocean Conservancy, in Washington, D.C.  “Adaptations can be tailored to address specific social and environmental weak points that exist in a community.

“This is really the first time that we’ve been able to go under the hood and really look at the factors that make a particular community in a borough or census are less or more vulnerable from changing conditions resulting from acidification. It gives us a lot of power so that we don’t just look at environmental issues but also look at the social story behind that risk.”

As for the southern part of the Alaska panhandle nearest British Columbia, Cooley said, “What we found is that there is a high relative risk compared to some of the other areas of Alaska and that is because the communities there undertake a lot of subsistence fishing, There tend not be a whole lot of commercial harvests in the fisheries there but they are very very important from a subsistence stand point… And they’re tied to species that we expect to be on the front line of acidification, many of the clam species that are harvested in that area and some of the crab species.”

Long term effects

Libby Jewett, Director of the NOAA Ocean Acidification Program  and author of  the pteropod study said,  “Acidification of our oceans may impact marine ecosystems in a way that threatens the sustainability of the marine resources we depend on.

“Research on the progression and impacts of ocean acidification is vital to understanding the consequences of our burning of fossil fuels.”

“Acidification is happening now,” Cooley said. “We have not yet observed major declines in Alaskan harvested species. In Washington and Oregon they have seen widespread oyster mortality from acidification.

“We don’t have the documentation for what’s happening in Alaska right now but there are a lot of studies staring up right now that will just keep an eye out for that sort of thing,  Acidification is going to be continuing progressively over the next decades into the future indefinitely until we really curb carbon dioxide emissions. There’s enough momentum in the system that is going to keep acidification advancing for quite some time.

“What we need to be doing as we cut the carbon dioxide, we need to find ways to strength communities that depend on resources and this study allows us to think differently about that and too really look at how we can strengthen those communities.

Faggetter said. “It’s one more blow to an already complex situation here, My study has been working particularly on eel grass on Flora Bank (pdf) which is a very critical habitat, which is going to be impacted by these potential industrial developments and that impact will affect our juvenile salmon and our salmon fishery very dramatically, that could be further worsened by ocean acidification.”

She said that acidification could also be a long term threat to plans in Prince Rupert to establish a geoduck fishery (pronounced gooey-duck).

The popular large 15 to 20 centimetre clam is harvested in Washington State and southern BC, but so far hasn’t been  subject to commercial fishing in the north.

NOAA said today’s study shows that by examining all the factors that contribute to risk, more opportunities can be found to prevent harm to human communities at a local level. Decision-makers can address socioeconomic factors that lower the ability of people and communities to adapt to environmental change, such as low incomes, poor nutrition, lack of educational attainment and lack of diverse employment opportunities.

NOAA’s Ocean Acidification Program and the state of Alaska are also developing tools to help industry adapt to increasing acidity.

The new NOAA study is the first published research by the Synthesis of Arctic Research (SOAR) program. which is supported by an inter-agency agreement between NOAA’s Office of Oceanic and Atmospheric Research and the Bureau of Ocean Energy Management (BOEM) Alaska Region.

The pteropod study was published in April in Proceedings of the Royal Society B. The ecological and economic study is published in Progress in Oceanography.

Enbridge files massive river oil spill study with the Joint Review Panel

Kitimat River map from Enbridge study
A Google Earth satellite map of the Kitimat River used as part of Enbridge Northern Gateway’s oil spill modelling study.

Enbridge Northern Gateway today filed a massive 11-volume study with the Joint Review Panel outlining possible scenarios for oil spills along the route including the Kitimat and Morice Rivers in British Columbia.

The study, carried out by three consulting firms, Stantec Consuting and AMEC Environmental & Infrastructure both of Calgary and RPS ASA of Rhode Island, is called “Ecological and Human Health Assessment for Pipeline spills.”

Overall the models created by study appear to be extremely optimistic, especially in light of recent events, such as the damning report on by the US
National Transportation Safety Board and the finding of violations by the US Pipeline and Hazardous Material Safety Administration with Enbridge operations during the 2010 Marshall, Michigan, spill and subsequent cleanup difficulties encountered by Enbridge.

The executive summary of the report begins by saying

This document presents conservatively developed assessments of the acute and chronic risk to ecological and human receptors in the unlikely event of a full bore pipeline break on the proposed Enbridge Northern Gateway Pipeline project. Three representative hydrocarbon types (condensate, synthetic oil
and diluted bitumen) were evaluated with releases occurring to four different rivers representing a range of hydrological and geographic characteristics, under both low-flow and high-flow conditions. The analysis indicates that that the potential environmental effects on ecological and human health from each hydrocarbon release scenario could be adverse and may be significant. However, the probability of the releases as considered in the assessment (i.e., full bore rupture, with no containment or oil recovery) is low, with return periods for high consequence watercourses ranging from 2,200 to 24,000 years. Therefore, the significant adverse environmental effects as described in this report are not likely to occur.

So the study says that it is “conservative” that means optimistic, that a full bore pipelink break with no containment or recovery is “an unlikely event” and would probably occur every 2,200 and 24,000 years. Not bad for a pipeline project that is supposed to be operational for just 50 years.

The summary does caution:

The analysis has also shown that the outcomes are highly variable and are subject to a great many factors including the location of the spill, whether the hydrocarbons are released to land or directly to a watercourse, the size of the watercourse, slope and flow volumes, river bed substrate, the amount of suspended particulate in the water, environmental conditions (such as the time of year, temperature and wind speeds, precipitation, etc.), the types of shoreline soils and vegetative cover and most significantly, the type and volume of hydrocarbon released.

The highly technical study is Enbridge’s official response to those intervenors who have “requested additional ecological and human health risk assessment studies pertaining to pipeline spills” and a request from the Joint Review Panle for more information about “the long term effects of pipeline oil spills on aquatic organisms (including the sensitivity of the early life stages of the various salmon species), wildlife, and human health.”

The report presents modelling on the release of three hydrocarbons, diluted bitumen, synthetic oil and condensate at four river locations along the pipeline route for their potential ecological and human health effects, under two flow regimes (i.e., high and low flow), broadly representing summer and winter conditions.

Modelling was done for four areas:

• Chickadee Creek: a low gradient interior river tributary discharging to a large river system
located up-gradient from a populated centre within the Southern Alberta Uplands region
• Crooked River: a low gradient interior river with wetlands, entering a lake system within
the Interior Plateau Region of British Columbia
• Morice River: a high gradient river system along the western boundary of the Interior
Plateau Region of British Columbia
• Kitimat River near Hunter Creek: a high gradient coastal tributary discharging to a large
watercourse with sensitive fisheries resources, downstream human occupation, and discharging to the Kitimat River estuary

In one way, the study also appears to be a partial victory for the Kitimat group Douglas Channel Watch because the model for the Kitimat River is based on a spill at Hunter Creek, which has been the subject of extensive work by the environmental group, but the consulting study is markedly optimistic compared to the scenario painted by Douglas Channel Watch in its presentations to District of Kitimat council.

The study describes the Kitimat River:

The hypothetical release location near Hunter Creek is southwest of Mount Nimbus, in the upper Kitimat  River watershed, and flows into Kitimat River, then Kitimat Arm, approximately 65 km downstream. The area is in a remote location and maintains high wildlife and fisheries values. The pipeline crossing near Hunter Creek is expected to be a horizontal direction drilling (HDD) crossing. The release scenario
assumes a discharge directly into Kitimat River…

The streambed and banks are composed of coarse gravel, cobbles and boulders. Shoreline vegetation (scattered grasses and shrubs) occurs in the channel along the tops of bars. Vegetation is scattered on the channel banks below the seasonal high water mark and more developed (i.e., grasses, shrubs and trees) bove the seasonal high water mark.

Wildlife and fish values for the Kitimat River are high: it is important for salmon stocks, which also provide important forage for grizzly bears, bald eagles and osprey on the central coast. The Kitimat River estuary, at the north end of Kitimat Arm, also provides year-round habitat for some waterbirds and seasonal habitat for staging waterfowl.

There is considerable recreational fishing, both by local people and through fishing guides, on Kitimat River, its estuary and in Kitimat Arm. There is also likely to be a high amount of non-consumptive recreational activity in the area, including wildlife viewing, hiking and camping. The Kitimat River estuary, for example, is well known for waterbird viewing.

While no fish were captured at this location during the habitat survey, salmonoid fry and coho salmon were observed downstream. Previously recorded fish species in the area include chinook, coho and chum salmon, rainbow trout, Dolly Varden, and steelhead trout.

However, the next paragraph appears to show that a full bore rupture on the Kitimat River would have widespread consequences because it would cover a vast area of First Nations traditional territory, saying

Aboriginal groups with traditional territories within the vicinity of the Kitimat River hypothetical spill scenario site include the Haisla Nation, Kitselas First Nation, Kitsumkalum First Nation, Lax-Kw’alaams First Nation and Metlakatla First Nation.

It also acknowledges:

Oral testimony provided by Gitga’at First Nation and Gitxaala Nation was also reviewed in relation to this hypothetical spill scenario, although the traditional territories of these nations are well-removed from the hypothetical spill site.

The report then goes on to list “the continued importance of traditional resources” for the aboriginal people of northwestern BC.

especially marine resources. People hunt, fish, trap and gather foods and plants throughout the area and traditional foods are central to feasting and ceremonial systems. Food is often distributed to Elders or others in the community. Written evidence and oral testimony reported that Coho, sockeye, pink, and spring salmon remain staples for community members. Halibut, eulachon, herring and herring roe,
various species of cod, shellfish, seaweed, and other marine life are also regularly harvested and consumed, as are terrestrial resources, including moose, deer, beaver, muskrat and marten. Eulachon remains an important trade item. Written evidence provides some information on seasonality of use and modes of preparation. Seaweed is dried, packed and bundled and preserved for later use. Each species of
salmon has its own season and salmon and other fish are prepared by drying, smoking, freezing or canning. Salmon are highly valued and often distributed throughout the community…

Some areas used traditionally are not depicted geographically. Upper Kitimat River from the Wedeene River to the headwaters has long been used for trapping, hunting, fishing and gathering of various foods. Fishing, hunting and gathering activities take place along the lower Kitimat River and its tributaries. Marine resources are collected in Kitimat Arm, Douglas Channel, and Gardner Canal. Old village and
harvesting sites are located along the rivers and ocean channels in this vicinity.

Intertidal areas are important and highly sensitive harvesting sites that support a diversity of species. Many intertidal sites are already over harvested and are therefore vulnerable. Conservation of abalone has been undertaken to help the species recover. Some concern was expressed in oral testimony regarding the
potential for archaeological sites and the lack of site inventory in the area. Oral testimony made reference to the Queen of the North sinking and the potential for a similar accident to result in human health and environmental effects.

A spill at Hunter Creek

The model says that all three types of floating oil in Kitimat River under high-flow conditions would reach approximately 40 kilometres downstream from Hunter Creek while low-flow conditions showed variation.

Under what the study calls low flow conditions, most condensate would evaporate. The bitumen would cause “heavy shore-oiling” for the first 10 kilometres, with some oiling up to 40 kilometres downstream.

The most sedimentation would occur for synthetic oil, and the least for condensate. Synthetic oil under both flow conditions would have the largest amounts deposited to the sediments. This is because of the low viscosity of synthetic oil, which allows it to be readily entrained into the water where it may combine with suspended sediments and subsequently settle. Synthetic oil under high-flow conditions would result in the most entrained oil and so the most extensive deposition to the sediment. Diluted bitumen, for both flow conditions, would result in the most deposited on shorelines, with the remainder (except that which evaporated or degraded) depositing to the sediments.
The condensate also would also have significant entrainment, but higher winds prevailing in under low flow conditions would enhance evaporation and rapidly lower concentrations in the water as compared to high-flow conditions. In all scenarios, a large amount of entrained oil and high concentrations of dissolved aromatics would move down the entire stretch of Kitimat River and into Kitimat River estuary.

Long term scenario

The modelling appears to be extremely optimistic when it reaches four to six weeks after the pipeline breach, especially in light of the continued cleanup efforts in Michigan, estimating that the “fast-flowing” nature of the Kitimat River would disipate all the different forms of hydrocarbon in the study saying

 a fast-flowing coastal river like Kitimat River, with gravel or cobble bottom would be affected by a large volume of crude oil released in a short period of time.

Oiling of shoreline soils is heavy in the reaches between the release point and 10 km downstream, becoming lighter to negligible beyond 10 km. Deposition of hydrocarbons to river sediment is greatest for the synthetic oil and diluted bitumen (high flow) scenarios extending up to 40 kilometres downriver, with predicted hydrocarbon concentrations in sediment approaching 1,000 mg/kg dry weight. Deposition of hydrocarbons to river sediment is considerably lighter for the diluted bitumen (low flow) and condensate scenarios. In these scenarios, oiling of river sediment is negligible….

It says that within four weeks of the end of the acute phase of the spill scenarios, concentrations in river sediments and river water would decline becoming quite low at the end of two years.

As for the affects on plants and invertebrates:

Oiling of shorelines would be extensive, particularly at assessment locations within 10 kilometres of the pipeline break location, under both the high and low flow scenarios, for synthetic oil and condensate. High loadings occur as far as 25 kilometres downstream, again asusming that damage would begin to disipate after four weeks declining over the next one to two years. Predicted effects are generally less severe for the diluted bitumen spill scenarios, due to lower expected loading of oil onto shorelines. Low to negligible shoreline oiling would occur for Kitimat River under most of the scenarios at the 40 kilometres assessment location and points downstream. Based on this assessment, very little oiling of shorelines would extend to the estuary and the environmental effects would be minimal.

The study goes on to say that the “model suggests that there would be no significant risk to fish health based upon chronic exposure to petroleum hydrocarbons  for the oil spill scenarios in Kitimat River or the potentially affected areas within the estuary, either at four weeks or one to two years following the hypothetical spill events. Risk to developing fish eggs in Kitimat River and estuary at four weeks and one to two years again indicate no significant risk to developing fish eggs in spawning gravels.”

It also claims that “chronic risks” to wildlife would be minimal, with some elevated risk for “muskrat, belted kingfisher, mallard duck, spotted sandpiper and tree swallow,” if they were exposed to synthetic oil. The muskrat, mallard duck and spotted sandpiper
could be vulnerable to bitumen and diluted bitumen.

It then claims that “no significant effects of chronic exposure (to all hydrocarbons) would occur for grizzly bear, mink, moose, river otter, bald eagle, Canada goose, herring gull or great blue heron for the Kitimat River hydrocarbon spill scenarios.”

Again, it appears from the sutdy that the spotted sandpiper would be most vulnerable to “bulk weathered crude oil exposure” includingcondensate, diluted bitumen and synthetic oil.

For the Kitimat section it concludes:

In the unlikely event of an oil spill, recovery and mitigation as well as the physical
disturbance of habitat along the watercourse would be likely to substantially reduce the exposure of wildlife receptors to hydrocarbons as compared to the scenarios evaluated here.

Link to Volume One of the Enbridge Northern Gateway Report Ecological and Human Health Assessment for Pipeline Spills