Abstract

Abstract To quantify the contribution of soil moisture to seasonal and annual variations in soil CO 2 efflux in a cool‐humid deciduous broadleaf forest, we measured soil CO 2 efflux during the snow‐free seasons of 2005–2008 using an automated chamber technique. This worked much better than manual chambers employing the same steady‐state through‐flow method. Soil CO 2 efflux (g C m −2 period −1 ) during the snow‐free season ranged from 979.8 ± 49.0 in 2005 to 1131.2 ± 56.6 in 2008 with a coefficient variation of 6.4 % among the 4 years. We established two‐parameter (soil temperature and moisture) empirical models, finding that while soil temperature and moisture explained 69–86 % and 10–13 % of the temporal variability, respectively. Soil moisture had the effect of modifying the temporal variability of soil CO 2 efflux, particularly during summer and early fall after episodic rainfall events; greater soil moisture enhanced soil CO 2 efflux in the surface soil layers. High soil moisture conditions did not suppress soil CO 2 efflux, leading to a positive correlation between normalized soil CO 2 efflux (ratio of the measured to predicted efflux using a temperature‐dependent Q 10 function) and soil moisture. Therefore, enhanced daily soil CO 2 efflux following heavy rainfall events could significantly reduce net ecosystem exchange (i.e. daily net ecosystem production) by 32 % on some days. Our results highlight the importance of precisely estimating the response of soil CO 2 efflux to changes in soil moisture following rainfall events when modeling seasonal carbon dynamics in response to climate change, even in humid monsoon regions.