Beaver ponds with more sediments store more nitrogen, simple mapping reveals

Simple mapping of beaver ponds can help land managers and conservationists in the West detect which ponds are sponging up nitrogen and which are releasing it

20 April 2023

A researcher helps launch a yellow inflatable raft holding a second researcher on a shallow pond surrounded by trees and low shrub, with mountains in the background. Two strings and a measuring tape are strung across the pond about a yard above the water surface.

Researchers measured the size, shape and depth and analyzed soil and water chemistry of a beaver pond system in the Bear River Mountains north of Salt Lake City.
Credit: Desneiges Murray

AGU press contact:
Rebecca Dzombak, +1 (202) 777-7492, [email protected] (UTC-4 hours)

Contact information for the researchers:
Desneiges Murray, University of New Hampshire, [email protected] (UTC- 4 hours)

WASHINGTON — Beaver ponds contain nitrogen, an essential nutrient that can become a pollutant when too much is present. Land managers need to know if beaver ponds are storing or releasing nitrogen, but chemical testing can be expensive. A new study shows how simple mapping of a beaver pond’s depth and sediment can tell managers whether it’s a nitrogen source or sink.

The study was published in the Journal of Geophysical Research: Biogeosciences, which publishes research on the interactions between biologic, geologic and chemical processes across Earth’s ecosystems.

Nitrogen is used in synthetic fertilizers and is naturally found in manure, so grazing and agriculture have added nitrogen pollution to rivers in the U.S. West, causing eutrophication downstream. Previous studies have found that nitrogen can be either higher or lower downstream from beaver ponds. But few studies have closely examined what happens to nitrogen within a beaver pond, leaving open the question of whether beaver ponds tend to be good or bad for nitrogen pollution and whether beavers should be reintroduced to the ecosystem.

“It depends on the river, but for sites like the one we studied, reintroducing beavers could be a wise decision,” said Desneiges Murray, a biogeochemist who led the study while at Utah State University. (She is now at the University of New Hampshire.) “These ecosystems evolved with beavers in the first place. So, the combined effects of less erosion, better resistance to forest fires, more water storage during droughts, and now the benefit of long-term nitrogen storage —  there are lots of reasons humans should be facilitating beaver recolonization into their natural habitats.”

A beaver pond complex in the Bear River Mountains, seen from above in a collage of images, with streams flowing in from the top and the dam and lodge visible.

Murray’s beaver complex field site in the Bear River Mountains, seen from above in a collage of images, with streams flowing in from the top. The pond retained about 15% of nitrogen runoff that flowed in with the stream in the low-oxygen backwater zone.
Credit: Desneiges Murray

During the 1600s to 1800s, between 25 to 160 million beavers were hunted to near extinction in the contiguous United States. By the late 1980s, they had recovered to between 6 and 12 million beavers; today, efforts to reintroduce beavers are taking place around the United States, with varying success and popularity.

The new study maps zones within a beaver pond system, called a complex, nestled in the Bear River Mountains north of Salt Lake City. Murray and her co-authors defined five zones based on water flow, pond depth, and sediment thickness and grain size. They gathered data on how much nitrogen and oxygen were in the water in different zones, collected samples of pond sediments, and took long cores of sediment to analyze nutrient changes over time. Then they mapped it all, paying special attention to the ratio of sediment depth and water depth.

“This new approach of looking at geomorphic units within a beaver complex is going to be helpful for understanding why beavers reduced nitrogen, or heavy metals, or acid mine drainage,” said Emily Fairfax, a hydrologist and self-described “beaver-ologist, if that were a thing” at California State University-Channel Islands. Fairfax was not involved in the study.

Most nitrogen enters beaver ponds as dissolved and particulate nitrogen. Once in the pond’s sediments, nitrogen can go through chemical transformations into other forms, such as ammonium, inert nitrogen gas, or reactive nitrogen dioxide gas, which can degrade ozone in the atmosphere.

The researchers found the beaver pond was storing up to 15% of the nitrogen that came in, mostly in the sediments of the backwater zone. The backwater zone has thicker organic-rich sediments and the low oxygen concentrations necessary for nitrogen to convert to inert nitrogen gas, which can be stored. Other zones, with less sediment or more oxygen, weren’t able to store as much nitrogen. It’s the first such correlation between a beaver pond’s small-scale geomorphology and nitrogen, and it opens the door to new ways of assessing nutrients in beaver ponds.

A big takeaway for Murray is that mapping the zones of beaver ponds is a powerful tool on its own — land managers could skip the chemical analyses if they’re just looking for an estimate of nitrogen cycling. Ponds with thicker organic-rich sediments and shallow, low-oxygen water are more likely to store nitrogen; faster-moving ponds with more oxygen and less sediment are more likely to release nitrogen.

“The experiments we conducted are difficult, time-consuming and expensive,” making mapping a simpler and cheaper alternative, Murray said. “This tight relationship we found between the shape of a beaver pond and its chemistry is really compelling, and those are basic measurements anyone with a science background could conduct.”

The new research is a case study of a specific site, but Fairfax thinks the mapping approach will be useful wherever beavers are found.

“They’ve identified the important zones for denitrification and nutrient processing, and that has a lot of potential because beavers don’t build the exact same dams,” Fairfax said. She also highlighted the importance of local studies.

“Policies won’t change unless decision makers see local data,” Fairfax said. “I haven’t seen many studies on beavers’ impact on nutrient loads in the West, so this is a really valuable case study to add to the literature.”


AGU ( is a global community supporting more than half a million advocates and professionals in Earth and space sciences. Through broad and inclusive partnerships, AGU aims to advance discovery and solution science that accelerate knowledge and create solutions that are ethical, unbiased and respectful of communities and their values. Our programs include serving as a scholarly publisher, convening virtual and in-person events and providing career support. We live our values in everything we do, such as our net zero energy renovated building in Washington, D.C. and our Ethics and Equity Center, which fosters a diverse and inclusive geoscience community to ensure responsible conduct.

Notes for journalists:

This paper has been made freely available until the end of the month. Download a pdf copy of the study here.

Paper title:

“Beaver pond geomorphology influences pond nitrogen retention and denitrification”


  • Desneiges (Deni) Murray (corresponding author), Janice Brahney, Department of Watershed Sciences, Utah State University, Logan, UT, USA
  • Bethany T. Neilson, Department of Civil and Environmental Engineering, Utah State University, Logan, UT, USA