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Mississippi Mud: More Water Behind Sediment Rise says USU Scientist


Thursday, Sep. 29, 2011


researchers with Mississippi mud samples
Watershed Sciences grad student Justin Stout, left, and faculty mentor Patrick Belmont examine sediment samples from the upper Mississippi River. Belmont's research appears in 'Environmental Science and Technology.’
Mississippi River and bluff in Wisconsin
The Mississippi River at Brady's Bluff, Wisconsin. While conservation measures are slowing agricultural erosion along the river, says USU scientist Patrick Belmont, erosion of stream banks and bluffs is increasing. Photo by Terence Hubert, USGS.

During the past several decades, upper Midwest state and local agencies have spent hundreds of millions of dollars on extraordinary conservation efforts to prevent the Upper Mississippi River from filling with mud, waste and excess nutrients. Yet the waterway, which winds through prime agricultural lands, has seen a ten-fold increase in sediment since the early 20th century.  

 

Fingers point to intensive farming practices and new-fangled farm implements. Critics charge that soil conservation, updated tillage practices and drainage solutions aimed at fixing the problem aren’t working.

 

That’s not the case, says Utah State University watershed scientist Patrick Belmont, who, with a team from multiple universities and research groups, recently completed a four-year study in the region.

 

“Conservation practices are decreasing agricultural soil erosion,” he says. “But the decreases are being offset by accelerated erosion of stream banks and bluffs.”

 

The cause? More water.

 

“While we haven’t reduced the amount of mud in the river, our study shows that the source of river sediment has profoundly shifted due to a significant increase in river discharge,” he says. “It’s just gotten wetter and we’re routing more water to the river more quickly than ever before.”

 

Belmont and colleagues from the University of Minnesota, the Science Museum of Minnesota, Johns Hopkins University, Minnesota Geological Survey, Seattle University, the University of Illinois, the University of Pennsylvania and the GFZ German Research Centre for Geosciences published findings from their study in the September 2011 online version of Environmental Science and Technology. The project was funded primarily by the National Science Foundation’s National Center for Earth-surface Dynamics, the Minnesota Pollution Control Agency and the Minnesota Department of Agriculture. Additional support was provided by USU’s Utah Agricultural Experiment Station, UM’s Limnological Research Center and the Minnesota Supercomputing Institute.

 

No one needs to remind the region’s riverfront residents of recent flooding events. Catastrophic floods in 1993 and 2008 floods caused economic losses in excess of one billion dollars. 2011 brought more misery as higher-than-normal snowpack melt and precipitation inundated farms and communities.

 

“In August 2007, a single weather event pounded parts of Minnesota with seventeen inches of rain in 24 hours,” Belmont says. “In Sept. 2010, six inches of rain covered 5,000 square miles in a 24-hour period.”

 

In addition to increased precipitation, water is being routed more quickly to the river via an ever-expanding network of underground drainage pipes.

 

“These changes in hydrology have increased the erosive power of the Mississippi and its tributaries,” he says.

 

Still, obvious changes in weather patterns aside, determining where the sediment is coming from and how much is transported is complicated, he says.

 

“Sediment is a natural part of rivers and identifying its sources and how it travels is tricky,” Belmont says. “But new tools that have become available in just the past several years allow us to track sediment as it moves through landscapes and rivers.”

 

To conduct the study, Belmont and his team employed geochemical fingerprinting along with a suite of geomorphic change -detection techniques, including both ground-based and aerial LiDAR (Light Detection and Ranging), a high-definition laser scanning tool used to map geologic surfaces.

 

“These tools allow us to examine areas at much higher resolution than has ever been possible,” he says. “We couldn’t have pulled off this study without this advanced technology.”

 

What the scientists are seeing, Belmont says, is increased erosion from stream banks and the river’s famous bluffs.

 

“This tells us we’re facing a new challenge in remediating nonpoint sediment pollution,” he says. “Management efforts must expand from soil erosion and agricultural practices to factors contributing to increased runoff.”

 

Related links:

 

Contact: Patrick Belmont, 435-797-3794, patrick.belmont@usu.edu

Writer: Mary-Ann Muffoletto, 435-797-3517, maryann.muffoletto@usu.edu



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