We measured the carbon isotopic composition (delta(13)C) of ecosystem respiration (delta(13)C(R)) in a subalpine forest across four growing seasons to examine whether patterns in delta(13)C(R) were consistent with those expected based on leaf-level gas-exchange theory, and in agreement with past studies of the relation between delta(13)C(R) and climate conducted across broad geographic regions. Conventional trends (i.e., less negative delta(13)C(R) with increased vapor pressure deficit (VPD) and air temperature (T(AIR)), and decreased soil moisture (theta)) were observed when we focused on the driest portions of average-wetness years and when delta(13)C(R) was positively correlated with nighttime ecosystem respiration (R(E)). Nonconventional trends (i.e., more negative delta(13)C(R) with decreased theta, and increased VPD and T(AIR)) were observed under specific climatic conditions (e. g., late snowmelt; extreme T(AIR) late in the growing season), and when delta(13)C(R) was negatively correlated with R(E). These nonconventional trends were independently corroborated using delta(13)C of extracted sugars from needles of dominant tree species at the site. Our results clearly demonstrate that the commonly reported relations between delta(13)C(R) and climate may break down depending on the interactions among environmental conditions. Efforts to model and predict the variability of delta(13)C(R) under changing climatic variables must characterize and parameterize the effects of unique combinations of weather conditions and variable hydrologic regimes, in combination with the susceptibility of photosynthetic isotope discrimination to extreme air temperatures.

• 出版日期2011-4-22