November 26, 2018
Stanford researchers find that a drying Canadian delta has driven muskrat population decline
Over the last half-century, Canada’s Peace-Athabasca Delta has been slowly drying. A new study shows this loss of habitat is likely responsible for the decline of semi-aquatic muskrat, and could have larger implications.
By Danielle Torrent Tucker
Indigenous communities have used muskrat fur to make clothing for generations and the animal’s meat is considered a seasonal delicacy. But it turns out decades of trapping are not primarily responsible for the animal’s decline across North America.
Instead, 46 years of satellite imagery show the Peace-Athabasca Delta has been drying since the 1970s, significantly reducing muskrat habitat. Stanford University researchers published their findings in the journal Environmental Research Letters.
Stanford research shows the drying trend in Canada’s Peace-Athabasca Delta is linked to the long-term decline in populations of the semi-aquatic muskrat. (Image credit: iStock)
“The ecological impacts are not limited to muskrat – they extend far beyond that,” said lead author Ellen Ward, a doctoral candidate in Stanford’s School of Earth, Energy & Environmental Sciences (Stanford Earth). “These results suggest that maybe the widespread continental‑scale decline in this animal is actually being driven by a large‑scale loss in wetland and aquatic habitat.”
More than just muskrat
Located in northeast Alberta, the Peace-Athabasca Delta is a Ramsar Wetland of International Importance and North America’s largest inland freshwater delta. The area comprises habitat for about 200 bird species as well as the threatened wood bison, which is among the largest land animals on the continent. The semi-aquatic muskrat is native to North America and an important ecological indicator since the species is highly sensitive to changing hydrologic conditions.
The researchers constructed maps of the 46-year record of surface water with Landsat satellite imagery from 1972 to 2017. Those images revealed that suitable muskrat habitat dwindled by 32 percent over a time when muskrat numbers also plummeted.
Muskrat serve as a convenient indicator for habitat loss because they construct easily counted “houses” for shelter. They rely on vegetation for food and to build their dwellings in lakes, small ponds, streams, rivers and wetlands – and within the delta, they reside in the areas that are most susceptible to drying out.
“We basically constructed a map showing where every muskrat house count was measured, and they’re located in these smaller water bodies,” Ward said.
Although the idea that the delta has been drying is not new, nobody had directly mapped the loss and it had never before been clearly linked to the long-term decline in muskrat. Now resource managers can see where exactly the drying has occurred over time.
“Our result is timely because this UNESCO World Heritage Site is currently being considered for designation as a wetland with “in danger” status,” said co-author Steven Gorelick, the Cyrus F. Tolman Professor in the Department of Earth System Science.
“If you look across the 46 years, you can see how much of the time each minute area was under water in those 46 years,” Ward said.
Previous research has suggested that the drying delta is primarily a result of climate change. If it continues, the decline of muskrat in the region will have impacts throughout the food chain, as muskrat are prey to many animals, including lynx, fox and mink. Their existence is critical to Indigenous people in the area, since muskrat are a part of treaty rights to hunt, fish and trap.
By addressing the importance of hydrology on the decline of an animal species, the researchers hope to encourage other scientists to move beyond the prevailing focus on plant-water relationships in ecohydrology.
“I hope that this paper shows hydrologists that looking at viable habitat through a water lens can actually tell you a lot about environmental change as it affects animals – traditionally, hydrologists have stayed away from that area,” Ward said. “I hope that we have contributed to ecohydrology by broadening the discussion.”
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Gorelick is a senior fellow at the Stanford Woods Institute for the Environment, director of the Global Freshwater Initiative at Stanford and director of the Hydrogeology and Water Resources Program at Stanford Earth. The research was supported by a Stanford Woods Institute Environmental Venture Project grant, a Stanford Freeman Spogli Institute for International Studies George P. Shultz Fellowship in Canadian Studies and a Stanford Graduate Fellowship.