Journal
SOIL BIOLOGY & BIOCHEMISTRY
Volume 46, Issue -, Pages 89-95Publisher
PERGAMON-ELSEVIER SCIENCE LTD
DOI: 10.1016/j.soilbio.2011.11.008
Keywords
Soil CO2 efflux; Santa Rosa Mountains; Soil microenvironments; Maximum soil respiration; Modified Arrhenius equation; Soil organic matter
Categories
Funding
- Kearny Foundation for Soil Science Research
- University of California, Riverside's Office of Undergraduate Education
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Soil respiration (R) has not been adequately studied at temperatures above 35 degrees C, which are common temperatures for soils in the southwestern United States and may be important for C dynamics in semi-arid regions. While frequently excluded from ecosystem models or set to 35 degrees C, the optimum temperature for soil R is poorly understood. Optimum temperatures are likely controlled by substrate availability, soil moisture content, and previous climate. To quantify the optimal temperature for soil R and hypothesized relationships, we collected soils from beneath and between plant canopies at three sites along a semi-arid elevation gradient. Processed soil samples were incubated at three soil moisture contents and soil R was measured at 6 temperatures, successively (25-55 degrees C). From these data, an activation energy for reaction kinetics and deactivation energy for enzyme functionality model was used to generate soil R curves from which two parameters were derived: R-max, the maximum rate of soil R and T-opt, the optimum temperature for soil R. R-max was significantly greater for soils at the highest elevation and at medium soil moisture content. T-opt was greater than 35 degrees C at all locations. In addition, Tom was significantly greater for soils with greater amounts of SOM but not significantly different along the elevation gradient or at different moisture contents. These results support inclusion of much higher optimum temperatures than currently used in many ecosystem and land-surface models and provide support for explaining variation in T-opt as regulated by substrate quantity within a site and general insensitivity across climate differences. (C) 2011 Elsevier Ltd. All rights reserved.
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