Newly published research from UNCG Biology’s Dr. Kevin Wilcox and colleagues will help scientists better predict how global changes – such as droughts, fires, and heat waves – will impact the health and sustainability of the Earth’s grassy ecosystems.
The article, published October 10, 2023, in Global Change Biology, provides key steps forward to improving mathematical models that forecast changes to our planet’s savannas, prairies, grasslands, and arctic tundras.
Grassy ecosystems provide many necessary resources and services to humans, including food production, pollinators, and carbon sequestration. They also serve as critical habitat for wildlife, such as elk and bison in North America.
Yet, when one looks deeper into humankind’s ability to predict how these ecosystems will persist under forthcoming global changes, the research lags far behind the predictive capacity for forests. Wilcox’s research on Earth system models is helping to close this gap.
Scientists use these models to simulate the effects of physical phenomena, such as droughts and heat waves, on landscapes. The mathematical equations that make up these models are strung together to create thousands of lines of computer code that ultimately provide an abstraction of reality. These models represent a wide range of ecological processes, such as rainfall penetrating the soil, insects defoliating a savanna, or heat stress causing plant and animal mortality.
“But if our models don’t accurately represent ecological processes, their predictions are meaningless,” said Wilcox.
An important facet to get right, Wilcox explains, is the ever-changing nature of these grassy systems.
“We can’t just assume that all the major components of the ecosystem, such as plant communities, will remain unchanged as droughts and heat waves continue to occur.”
One of the biggest challenges is how grasses are represented. Currently, many models represent grasses as either miniature trees or as a ‘green slime’ that exists on the surface of the planet. The authors say this representation may be part of why the models have had trouble matching real-world observations in grassy ecosystems.
“Better collaboration between empiricists and modelers will also be key for improving herbaceous dynamics within ecosystem models,” adds Wilcox.
Implementing these changes, the authors say, will be vital in helping guide public policy and management of these important ecosystems in the future, when droughts and deluges are more frequent and extreme, disturbances such as fires are more severe, and human pressures continue.
Story by Elizabeth Keri, College of Arts & Sciences
Lead photo by Jiyoung Park, UNCG