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$4.2 million NSF grant helps biologist gather large-scale river measurements

Kansas State University


IMAGE: By gathering large-scale information on rivers, Kansas State University biologist Walter Dodds is creating a better biological picture of river systems across North America and Asia. view more

Credit: Kansas State University

MANHATTAN, KANSAS -- A Kansas State University researcher is creating a better biological picture of river systems across North America and Asia.

Walter Dodds, university distinguished professor of biology, is part of a collaborative five-year, $4.2 million National Science Foundation project to better understand how climate change affects river systems. The research team -- which includes more than 11 researchers from more than nine institutions -- wants to study how changes in precipitation and temperature as well as human activities influence river systems in the U.S. and Mongolia.

For his portion of the project, Dodds will gather large-scale biological information on rivers. He will measure the metabolism of nine rivers across the U.S. Great Plains, Great Basin and Mountain Steppes -- including the Platte, Niobrara, Humboldt, Bear and Snake rivers -- as well as nine similar rivers in Mongolia. River metabolism includes oxygen production and consumption from bacteria, algae, plants and animals in the rivers.

"We really don't know a lot about how rivers function and their biological communities," Dodds said. "What is feeding these rivers? Is it leaves falling or is it algae growing and feeding insects and fish? We hope to find out by gathering these measurements."

While Dodds is measuring the river metabolism, other researchers will study food webs, biodiversity traits of fish and invertebrates, and physical and biological characteristics of the riparian zone and basin.

The measurements will provide comparisons between U.S. and Mongolian rivers, Dodds said. Mongolian rivers are relatively pristine with few dams and little agriculture around them. By comparison, North American rivers have been affected by non-native fauna, dams and other human activities.

The large-scale measurements also will provide valuable information about different river ecosystems, including mountains, drylands, grasslands and forests.

"A lot of research has been performed on forest systems, but not so much on grassland and dryland streams and rivers," Dodds said. "We're going to look at a global sense of these grassland and dryland rivers and see if they are functionally different than the ones in forest and temperate areas."

To gather data, Dodds will use two new forms of equipment. One type uses sound waves to measure river depth and water flow speed. The equipment can map the bottoms of rivers and measure how much water is present and how fast it is moving. The second equipment type involves oxygen electrodes that can measure oxygen dissolved in water and how it changes throughout the day.

"There are only a moderate number of these measurements in many rivers around the world," Dodds said. "It is only recently that technological advances have made it possible and now we can gain useful information on the biological activity of rivers."


James Thorp, University of Kansas professor of ecology and evolutionary biology and senior scientist with the Kansas Biological Survey, is leading the National Science Foundation project. Co-principal investigators include Mark Pyron, Ball State University; Jon Gelhaus and Alain Maasri, Academy of Natural Sciences of Drexel University; Bazartseren Boldgiv, National University of Mongolia; Olaf Jensen, Rutgers University; Scott Kenner, South Dakota School of Mines and Technology; Dan Reuman, University of Kansas; Sudeep Chandra, University of Nevada Reno; and Barbara Hayford, Wayne State College.

Kansas State University's Division of Biology is in the College of Arts & Sciences.

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