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Embracing a new paradigm for temperature sensitivity of soil microbes

Charlotte J. Alster, Joseph C. von Fischer, Steven Allison, Kathleen K. Treseder

2020Global Change Biology105 citationsDOIOpen Access PDF

Abstract

Abstract The temperature sensitivity of soil processes is of major interest, especially in light of climate change. Originally formulated to explain the temperature dependence of chemical reactions, the Arrhenius equation, and related Q 10 temperature coefficient, has a long history of application to soil biological processes. However, empirical data indicate that Q 10 and Arrhenius model are often poor metrics of temperature sensitivity in soils. In this opinion piece, we aim to (a) review alternative approaches for characterizing temperature sensitivity, focusing on macromolecular rate theory (MMRT); (b) provide strategies and tools for implementing a new temperature sensitivity framework; (c) develop thermal adaptation hypotheses for the MMRT framework; and (d) explore new questions and opportunities stemming from this paradigm shift. Microbial ecologists should consider developing and adopting MMRT as the basis for predicting biological rates as a function of temperature. Improved understanding of temperature sensitivity in soils is particularly pertinent as microbial response to temperature has a large impact on global climate feedbacks.

Topics & Concepts

Sensitivity (control systems)Arrhenius equationClimate changeSoil waterAdaptation (eye)Environmental scienceLapse rateBiochemical engineeringEcologySoil scienceEconometricsBiological systemAtmospheric sciencesChemistryMathematicsBiologyPhysicsPhysical chemistryEngineeringNeuroscienceElectronic engineeringActivation energySoil Carbon and Nitrogen DynamicsMicrobial Community Ecology and PhysiologyPlant Water Relations and Carbon Dynamics
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