A study from Colorado State University’s Department of Soil and Crop Sciences and the Graduate Degree Program in Ecology found that regenerative practices – including integrating crop and livestock systems – were successful as long-term carbon storage solutions.
The paper, “Restoring particulate and mineral-associated organic carbon through regenerative agriculture,” was recently published in Proceedings of the National Academy of Sciences (PNAS). The study was led by ecology Ph.D. candidate Aaron Prairie, along with two co-authors: research scientist Alison King and M. Francesca Cotrufo, professor of soil and crop sciences and Prairie’s advisor.
Their research presented a global systemic meta-analysis looking beyond the impact of regenerative agricultural practices on total soil organic carbon (SOC) alone, instead looking at two main pools: particulate organic carbon (POC) and mineral-associated organic carbon (MAOC).
Not all soil carbon is created equally
The regeneration of SOC in agricultural soils is one of the most realisable nature-based solutions available to mitigate global warming and sustain food productivity for the future. Over the past two years, Prairie looked at studies featuring experiments analysing the effects of regenerative agricultural practices compared to conventional or control practices and how these different practices increase SOC.
Rather than just looking at total soil organic carbon, he broke it up into particulate organic carbon (POC) and mineral-associated organic carbon (MAOC). Prairie said, “That’s important because they behave very differently in soil,” noting that POC cycles faster, creating different implications for management and carbon sequestration.
Cotrufo first demonstrated that two functionally different pools of carbon are formed through different processes, and her former Ph.D. student, Katherine Rocci, showed they respond differently to global changes. Cotrufo said, “This analysis is the first one to demonstrate the differential impact of regenerative practices on both the particulate organic matter and the mineral associated organic matter. There has been meta-analysis before, but on a small subset of management, and only looking at the total carbon. We found that if we study POC and MAOC separately, we can better inform management about what different conditions promote better outcomes.”
A confirmation of regenerative agriculture
One of the most important findings Cotrufo noted is that regenerative practices have an overall positive impact on SOC pools. She said, “There are a lot of nuances and variables across the studies that need further research. But it’s a big call for agriculture to move towards a regenerative management model.”
Especially when these practices are combined. Prairie said, “We know that they all work individually, but this study also showed the huge potential for the stacked effects even more.”
Decades ago, to increase productivity and lower production costs, the industry largely separated animal production from crop production, focussing on specialisation. Cotrufo said, “We have increased productivity, but that has come at a huge cost to the environment.”
The study showed tremendous potential to greatly increase SOC pools through synergistic interactions between multiple practices, such as polyculture farming, cover cropping, integrated crop-livestock systems and even tillage.
While helpful for plant growth, conventional tillage can also lead to erosion and loss of soil nutrients. But when other regenerative practices are in place, it’s possible, Prairie said. “Tillage has a much less negative effect on soil carbon if you are doing things like cover crops and polyculture and other sorts of regenerative practices.”
Patience
Another finding is that like all good things, increasing SOC takes time. Prairie said his analysis shows that impacts from regenerative practices don’t begin showing up in terms of soil carbon until approximately six years after implementation.
That’s a potential problem because most SOC programs – including carbon markets, which allow farmers and ranchers to sell carbon credits equal to the amount of carbon dioxide their land has sequestered – quantify SOC change in a five-year-timeline, which means they aren’t going to capture this benefit of regenerative agriculture. Cotrufo said, “You have to set the system in motion for plants, microbes and soil minerals to work to regain that organic matter. It’s not a quick fix.”
Looking to the past for agriculture’s future
This type of integrated management model was typical before the industrialisation of agriculture. The farmers in the 1800s and early 1900s had small operations that were diversified. Some producers are returning to that model and demonstrating how that can be effective in regenerating soil carbon today.
This analysis opens the door to looking at regenerative agriculture in new ways, Prairie said. “It shows that there’s a lot that we don’t understand about specific mechanisms of carbon formation and that more research needs to be done into the combination of these different practices and their viability.
Cotrufo said, “This paper shows that regenerative integration and regenerative principles definitely work. Optimising them for context is where we need to work next.”