Apparently, dirt is not welcome at most synchrotrons (also known as light sources) as was noted in my November 13, 2022 posting about Saskatoon’s synchrotron being used to analyze some soil from Hawaii. This time, according to a September 4, 2024 Canadian Light Source (CLS) news release by Rowan Hollinger (also received via email), the soil is from Kansas and there appears to be a second synchroton involved in this research,

With carbon dioxide levels in the atmosphere increasing in recent decades, there is a growing urgency to find strategies for capturing and holding carbon.

Researchers from Kansas State University (K-State) are exploring how different farming practices can affect the amount of carbon that gets stored in soil. Using the Canadian Light Source (CLS) at the University of Saskatchewan (USask) and the Advanced Light Source in Berkeley, California, they analyzed soil from a cornfield in Kansas that had been farmed with no tilling for the past 22 years. During that time, the farm used a variety of different soil nitrogen management practices, including no fertilizer, chemical fertilizer, and manure/compost fertilizer.

“We were trying to understand what the mechanisms are behind increasing soil carbon storage using certain management practices,” says Dr. Ganga Hettiarachchi, professor of soil and environmental chemistry at Kansas State University. “We were looking at not just soil carbon, but other soil minerals that are going to help store carbon.”

As has been shown in other studies, the K-state researchers found that the soil enhanced (treated) with manure or compost fertilizer stores more carbon than soil that received either chemical fertilizer or no fertilizer. More exciting though, says Hettiarachchi, the ultrabright synchrotron light enabled them to see how the carbon gets stored: they found that it was preserved in pores and some carbon had attached itself to minerals in the soil.

The team also found that the soil treated with manure or compost contained more microbial carbon, an indication that these enhancements support more microorganisms and their activities in the soil. In addition, they identified special minerals in the soil, evidence Hettiarachchi says, that the treatments contribute to active chemical and biological processes.

“To my knowledge, this is the first direct evidence of mechanisms through which organic enhancements improve soil health, microbial diversity, and carbon sequestration.”

Because synchrotron imaging is non-destructive, the K-state researchers were able to observe what was going on in soil aggregate (clumps) without having to break up the soil; essentially, they were looking at the carbon chemistry in its natural state.

“Collectively, studies like this are going to help us to move forward to more sustainable, more regenerative agriculture practices that will protect our soils and environment as well as help feed growing populations, says Hettiarachchi. “As well, understanding the role of the different minerals, chemicals, and microbes involved will help improve models for predicting how different farming practices affect soil carbon storage.”

Here’s a link to and a citation for the paper,

Direct evidence on the impact of organic amendments on carbon stabilization in soil microaggregates by Pavithra S. Pitumpe Arachchige, Ganga M. Hettiarachchi, Charles W. Rice, James J. Dynes, Leila Maurmann, A. L. David Kilcoyne, Chammi P. Attanayake. Soil Science Society of America Journal (2024) DOI: https://doi.org/10.1002/saj2.20701 First published: 21 June 2024

This paper is behind a paywall.