Earthquake scientists reveal how overplowing weakens soil at experimental farm – UW News
Skip to content
All the UW
Current site
Search scope
All the UW
Current site
Enter search text
University of Washington
University of Washington
Students
Parents
Faculty & Staff
Alumni
Menu
About
Stories
All stories
News releases
UW News blog
UW Notebook
For Washington
Official notices
UW in the media
Multimedia
Video stories
Podcasts
Soundbites/b-roll
Interactives
Experts
Directory
Expert quotes
COVID-19 experts
Speakers Bureau
Media contacts
For Journalists
For researchers
For researchers & staff
Submit to UW Today
Media Training
UW NEWS
UW NewsThe latest news from the UWEarthquake scientists reveal how overplowing weakens soil at experimental farm
Environment | News releases | Research | Science
March 19, 2026
Earthquake scientists reveal how overplowing weakens soil at experimental farm
Gillian Dohrn UW News
A plot of experimental land at Joe Collins’ Field near Harper Adams University, where University of Washington researchers travelled to collaborate on an agroseismology experiment examining the impact of tilling on soil moisture. Photo: Marine Denolle/University of Washington
Researchers (from left to right) Ethan Williams, Joe Collins, Simon Jeffrey lay the fiber optic cable just below the surface of a test near Harper Adams University. Photo: Marine Denolle/University of Washington
Senior author Marine Denolle, a UW associate professor of Earth and space sciences, poses in front of the test field with her daughter, Catherine, on a rainy field day. Photo: Marine Denolle/University of Washington
Ethan Williams, a former UW postdoctoral researcher in Earth and space sciences, now an assistant professor at UC Santa Cruz, uses the highly portable DAS data collection system at the experimental farm. Photo: Marine Denolle/University of Washington
Previous imageNext image
Plowing, or tilling, is an age-old agricultural practice that readies the soil for planting by turning over the top layer to expose fresh earth. The method — intended to improve water and nutrient circulation — remains popular today, but concerns about soil degradation have prompted some to return to regenerative methods that disturb the soil less.
In a new study, a team led by University of Washington researchers examined the impact of tilling on soil moisture and water retention using methods originally designed for monitoring earthquakes. Researchers placed fiber optic cables alongside fields at an experimental farm in the United Kingdom and recorded ground motion from plots receiving different amounts of tillage and compaction from tractor tires pulling farm equipment.
The study, published March 19 in Science, shows that tilling and compaction disrupt intricate capillary networks within the soil that give it a natural sponge-like quality.
“This study offers a clear explanation for why the process of tillage, one of humanity’s oldest agricultural activities, changes the structure of soil in ways that affect how it soaks up water,” said co-author David Montgomery, a UW professor of Earth and space sciences.
The link between tilling and soil degradation has been established for quite some time, but the rationale is less robust.
“It’s counterintuitive,” Montgomery said.
Tilling is supposed to create holes for water to reach the roots of plants, but it breaks these small channels in the soil instead, causing rain to pool on the surface and form a muddy crust. Over time, this can increase erosion and flood risk. The researchers observed this phenomenon in detail using seismological methods.
For the past decade or so, physical scientists have been exploring ways to harness the fiber optic cable network to make remote observations. They use a technique called distributed acoustic sensing, or DAS, that records ground motion based on cable strain. Because the technology is so sensitive, it can also capture the speed at which sound waves pass through a substance, which is called seismic velocity.
When soil gets wet, seismic velocity changes. Sound moves slower through mud than dry dirt.
“We wanted to find out whether seismic tools could be used to understand how soil — under different treatment regimens — would respond to environmental variability,” said senior author Marine Denolle, a UW associate professor of Earth and space sciences.
An experimental farm near Newport in the United Kingdom, affiliated with Harper Adams University, turned out to be an ideal testing ground for their experiment.
The farm is split into rows that have received consistent cultivation for more than two decades.
There are no-till rows, rows tilled 10 centimeters deep and rows tilled 25 centimeters. Compaction is a byproduct of tilling caused by tractors. Different levels of compaction were tested by modulating tractor tire pressure.
“We took advantage of a natural experiment that had already been done, but just not yet measured,” Montgomery said.
The researchers lined their experimental plots with a fiber optic cable. They collected continuous ground motion data for 40 hours and combined it with weather data over the same period, which featured light to moderate rainfall and mild temperatures.
“We observed the natural vibration of the ground and found that it is really sensitive to environmental factors, including precipitation,” said Qibin Shi, lead author and former UW postdoctoral researcher of Earth and space sciences, now at the Chinese Academy of Sciences.
They determined how each cultivation strategy impacted the soil’s response to rainfall by comparing trends in seismic velocity across study sites. Shi developed various models to process the data and help the researchers understand seismic velocity in terms of soil moisture.
The method is straightforward, inexpensive and offers far better spatial and temporal resolution than previous monitoring tools.
The researchers believe it could help farmers understand how to manage their land, provide real time flooding alerts, improve earth systems models by refining estimates of atmospheric water content and better inform seismic hazard maps with data on liquefaction risk.
Additional co-authors include Abigail Swann, a UW professor of atmospheric and climate science, Nicoleta C. Cristea, a UW research assistant professor of civil and environmental engineering, Ethan Williams from the University of California Santa Cruz, Nan You formerly at Purdue University, Simon Jeffery, Joe Collins, Ana Prada Barrio and Paula A. Misiewicz from Harper Adams University, Tarje Nissen-Meyer from the University of Exeter
This study was funded by The Pan Family Fund, the Murdock Charitable Trust, the UW College of the Environment Seed Fund, the David and Lucile Packard Foundation, and a National Environmental Research Council cross-disciplinary research capability grant.
For more information, contact Denolle at mdenolle@uw.edu.
Tag(s): College of the Environment • David Montgomery • Department of Earth and Space Sciences • Marine Denolle • Qibin Shi • Research Makes America
Post navigation
Previous articleVideo: How do plants know when to bloom? Spring flowering explained by UW chronobiologistNext articleQ&A: UW professor on Iranian regime, US-Israeli strikes and a divide among the Iranian diaspora
Research Makes America
UW research makes America healthier, safer and more prosperous. But those gains are now at risk.
Learn more about how research matters and visit UW Impact to sign up for alerts about threats to this important work.
News releases
Read more news releases
More
ConnectUW Experts
Weather
Artificial intelligence
Wildfires and Smoke
Full directory
Search UW News
Search for:
Latest news video
Video: How do plants know when to bloom? Spring flowering explained by UW chronobiologist 1 week ago
More
UW Today Newsletter
Subscribe
UW Today Daily
UW Today Week in Review
For UW employees
Submission guidelines
Submission form
University of Washington
Be boundless
Connect with us:
Facebook
Twitter
Instagram
YouTube
LinkedIn
Pinterest
Accessibility
Contact Us
Jobs
Campus Safety
My UW
Rules Docket
Privacy
Terms
Newsletter
© 2026 University of Washington | Seattle, WA |
The University of Washington’s research, led by Marine Denolle and David Montgomery, investigated the detrimental effects of tilling on soil properties utilizing innovative seismic monitoring techniques. This study, published in *Science*, explored the impact of various tillage practices – including depths of tilling and compaction from tractor tires – on an experimental farm in the United Kingdom, affiliated with Harper Adams University. The research team employed distributed acoustic sensing (DAS) technology, originally developed for earthquake monitoring, to measure ground motion and seismic velocity within the soil. The study revealed that tilling disrupts capillary networks and increases soil bulk density, leading to a reduction in water retention capacity and increased susceptibility to erosion. Researchers meticulously documented the changes in seismic velocity – a direct indicator of soil moisture – across different treatment regimes, demonstrating a clear correlation between tilling, compaction, and altered soil behavior in response to rainfall. The team, with collaborators including Qibin Shi and Abigail Swann, leveraged this data to develop models for predicting soil moisture and refining earth system models, highlighting the potential of DAS for applications ranging from flood alerts to improved seismic hazard maps. The research was funded by multiple institutions, including The Pan Family Fund and the David and Lucile Packard Foundation, and represents a novel application of seismological principles to agricultural soil science. |