Tile drainage directly related to nitrate loss

But a recent study shows that the most heavily tile-drained areas of North America are also the largest contributing source of nitrate to the Gulf of Mexico, leading to seasonal hypoxia. In the summer of 2010 this dead zone in the Gulf spanned over 7,000 square miles.

Scientists from the U of I and Cornell University compiled information on each county in the Mississippi River basin including crop acreage and yields, fertilizer inputs, atmospheric deposition, number of people, and livestock to calculate all nitrogen inputs and outputs from 1997 to 2006. For 153 watersheds in the basin, they also used measurements of nitrate concentration and flow in streams, which allowed them to develop a statistical model that explained 83 percent of the variation in springtime nitrate flow in the monitored streams. The greatest nitrate loss to streams corresponded to the highly productive, tile-drained cornbelt from southwest Minnesota across Iowa, Illinois, Indiana, and Ohio.

This area of the basin has extensive row cropping of fertilized corn and soybeans, a flat landscape with tile drainage, and channelized ditches and streams to facilitate drainage.

“Farmers are not to blame,” said University of Illinois researcher Mark David. “They are using the same amount of nitrogen as they were 30 years ago and getting much higher corn yields, but we have created a very leaky agricultural system. This allows nitrate to move quickly from fields into ditches and on to the Gulf of Mexico. We need policies that reward farmers to help correct the problem.”

David is a biogeochemist who has been studying the issue since 1993. “We've had data from smaller watersheds for some time, but this new study includes data from the entire Mississippi Basin. It shows clearly where across the entire basin the sources of nitrate are.

“A lot of people just want to blame fertilizer, but it's not that simple,” David said. “It's fertilizer on intensive corn and soybean agricultural rotations in heavily tile-drained areas. There is also an additional source of nitrogen from sewage effluent from people, although that is a small contribution. It's all of these factors together.”

David said that ripping out all of the drainage tiles is not a viable option. “Creating wetlands and reservoirs such as Lake Shelbyville can remove nitrate by holding the water back and letting natural processes remove it, but that's not a solution. It's expensive and we can't flood everyone's land to stop nitrate. That's not going to happen.”

“The problem is correctable but will take a concerted effort to change the outcome, with some of the solutions expensive. Installing small wetlands or bioreactors at the end of tile lines that remove nitrates before they flow into the ditch do work, but would cost thousands of dollars per drain. Who's going to pay for that?” David said.

Cover crops can hold the nutrients so they are available in the spring, and are reasonably cheap, David said, but can increase the farmer's risk for the following crop. “So if a farmer plants a cover crop and his neighbor doesn't, he may be at a disadvantage.”

David believes that the system can be improved by focusing conservation efforts on the areas of the country that are contributing the most nitrate loss and establish an incentive program for farmers to utilize one or more practices known to reduce nitrate losses from tile lines.

Encouraging farmers to apply the right amount of nitrogen in the spring rather than the fall (or to sidedress), establishing a more complex cropping system which incorporates cover crops or even biofuel crops such as Miscanthus or switchgrass when there are markets, and installing end-of-pipe solutions such as controlled drainage, bioreactors, or wetlands are some of the efforts David suggests would help reduce nitrate loss.

“Until we change the payment system beyond our focus on yield alone, we're not going to make much progress in reducing nitrate losses. We also haven't developed voluntary programs that really address nitrate loss from tiles, and we need to provide more incentive and cost-share funding to producers. We may also need regulation. We could say to producers, if you buy fertilizer, you've got to do one of these five things,” he said. “There's no one solution.”

Dennis McKenna of the Illinois Department of Agriculture said “Dr. David's work is an important contribution in helping producers and policy makers identify the most critical areas. Hopefully this information will be used to develop a focused national and state effort to reduce nutrient losses to surface water.”

Sources of Nitrate Yields in the Mississippi River Basin was published in the September-October 2010 issue of the Journal of Environmental Quality.

This research was funded by the National Science Foundation Biocomplexity in the Environment/Coupled Natural-Human Cycles Program. Authors in addition to David were Greg McIsaac from the University of Illinois and Laurie Drinkwater from Cornell University.

Media Contact

Debra Levey Larson EurekAlert!

More Information:

http://www.illinois.edu

All latest news from the category: Ecology, The Environment and Conservation

This complex theme deals primarily with interactions between organisms and the environmental factors that impact them, but to a greater extent between individual inanimate environmental factors.

innovations-report offers informative reports and articles on topics such as climate protection, landscape conservation, ecological systems, wildlife and nature parks and ecosystem efficiency and balance.

Back to home

Comments (0)

Write a comment

Newest articles

Lighting up the future

New multidisciplinary research from the University of St Andrews could lead to more efficient televisions, computer screens and lighting. Researchers at the Organic Semiconductor Centre in the School of Physics and…

Researchers crack sugarcane’s complex genetic code

Sweet success: Scientists created a highly accurate reference genome for one of the most important modern crops and found a rare example of how genes confer disease resistance in plants….

Evolution of the most powerful ocean current on Earth

The Antarctic Circumpolar Current plays an important part in global overturning circulation, the exchange of heat and CO2 between the ocean and atmosphere, and the stability of Antarctica’s ice sheets….

Partners & Sponsors