Marshall, John
- University of Idaho
P>1. Applying Keeling plot techniques to derive delta 13C of respiratory input in a closed non-equilibrated chamber can lead to large errors because steady-state diffusion rules are violated in a non-steady-state environment. To avoid these errors, respiratory delta 13C can be derived using equilibrated closed chambers.2. We introduce a new method to obtain stem respired CO2 delta 13C (delta(st-r)) with closed equilibrated stem chambers (E-SC). We present a theoretical model describing the equilibration process, test the model against field data and find excellent agreement. The method is further tested by comparing it with closed non-equilibrated stem chambers (NE-SC); we found no difference between these methods.3. Our theoretical model to describe CO2 diffusion from the respiratory pool into the chamber and the equation to derive the delta 13C of the efflux are general. They could be applied to other ecosystem components (e.g. soils).4. Our method is easy to implement, cost effective, minimizes sources of error and allows for rigorous leak detection. One major limitation is its inability to detect rapid change; the equilibration process requires 15 +/- 2 h. A second limitation is that it cannot be used for species that produce abundant pitch at sites of stem wounding (e.g. Pseudotsuga menziesii).5. Investigating delta 13C of CO2 respired by different ecosystem components is necessary to interpret delta 13C of ecosystem respiration. This parameter has major implications with respect to global carbon cycle science.
closed chamber; diffusion; flux; fractionation; Keeling plot; pool; soil respiration; stem respiration
Functional Ecology
2009, volume: 23, number: 6, pages: 1050-1058
Publisher: WILEY-BLACKWELL
Ecology
https://res.slu.se/id/publ/88090