COS 17-1 - Effects of thinning, lime addition, and litter removal on soil respiration in red pine plantations in Ontario, Canada

Tuesday, August 5, 2008: 8:00 AM
102 E, Midwest Airlines Center
Yuanying Peng, Natural Sciences Division, College of DuPage, Glen Ellyn, IL, S. C. Thomas, Faculty of Forestry, University of Toronto, Toronto, ON, Canada and Dalun Tian, Forest Ecology Section, Faculty of Life Science, Central South University of Forestry and Technology, Changsha, China
Background/Question/Methods

Carbon dioxide emission from soils plays a critical role in biogeochemical cycling of carbon in terrestrial ecosystems. Although most temperate forests are actively managed for timber production, few data exist regarding the long-term effects of forest management on soil carbon dynamics. In order to evaluate the influence of forest management practices on soil respiration for the understanding of carbon sequestration, we examined the effects of thinning, lime addition and litter removal treatments on soil respiration in 27-year old red pine (Pinus resinosa Ait.) plantations in Ontario, Canada. We measured soil respiration rate (FCO2), soil temperature (Tsoil), soil moisture (Wg), soil depth to C horizon, soil organic matter contents and soil pH, in the growing seasons of 2004 and 2005.

Results/Conclusions

All treatments had immediate effects on FCO2. In the first year after thinning, mean FCO2 was higher in thinned sites than controls under lime addition. Soil FCO2 significantly decreased in litter removal plots in both thinned and control sites while soil FCO2 increased in limed plots only in conjunction with thinning. Tsoil and Wg were higher in thinned sites than in control sites, and litter removal also had significant effects on Tsoil and Wg. In contrast to the large effects in the first year, there were no significant treatment effects on FCO2, soil temperature and moisture in the second year post-treatment. Our results indicate that the short-term pulse in FCO2 following forest thinning was driven by an increase in microbial respiration related to fine root decay; however, the magnitude of this heterotrophic respiration pulse depended strongly on soil conditions, being most pronounced in plots with both liming and litter removal. Our results suggest that losses of soil carbon following thinning may be mitigated by maintaining soil conditions less favourable for microbial decomposers, such as avoiding liming immediately following thinning in managed forest stands.

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