Adrien Finzi / Rose Abramoff
September 25, 2017
New microbial model explains observed relationship between heterotrophic respiration and temperature.
This study developed a new model of microbial soil decomposition that successfully captured the changing relationship between temperature and microbial respiration during the growing season. The scientists showed that the soil microbial response to plant inputs depends on the nitrogen content of the added plant material.
The team developed a new model for predicting soil response to changes in soil temperature, moisture, plant inputs, and stoichiometry. This model is simple and based on well-defined physical and biological properties and could be developed to model microbial activity at larger scales.
Microorganisms that grow in the soil, like bacteria and fungi, affect how much carbon resides in the soil and how much is released to the atmosphere as carbon dioxide (CO2). Mathematical models used to make climate change predictions often struggle to capture the activity of soil microbes in realistic ways. This study uses well-established descriptions of water and temperature effects on soil microbes to predict rate of carbon and nitrogen cycling in the soil. The new model (called the Dual Arrhenius Michaelis-Menten–Microbial Carbon and Nitrogen Physiology, or DAMM-MCNiP), reproduces the changing relationship between temperature and microbial respiration during the growing season. The study also shows using a theoretical addition of root secretions that the microbial response depends on the nitrogen content of the added plant material. This model is simple and based on well defined physical and biological properties and could be developed to model microbial activity at larger scales.
BER Program Manager
Terrestrial Ecosystem Science, SC-23.1
Adrien Finzi and Rose Abramoff
Boston University and Lawrence Berkeley National Laboratory
email@example.com and firstname.lastname@example.org
U.S. Department of Energy, grants DE-SC0006916, DE-SC0012288, and DE-AC02-05CH11231; National Science Foundation (DEB 1237491); U.S. Department of Agriculture grant 2014-67003-22073; and American Association of University Women Doctoral Dissertation Fellowship.
Abramoff, R.Z., E.A. Davidson, A.C. Finzi. “A parsimonious modular approach to building a mechanistic belowground carbon and nitrogen model.” JGR Biogeosciences 122(9), 2418–2434 (2017). [DOI:10.1002/2017JG003796].
Lawrence Berkeley National Laboratory - TES SFA