Oxygen isotope content of CO2 in nocturnal ecosystem respiration:: 2.: Short-term dynamics of foliar and soil component fluxes in an old-growth ponderosa pine forest -: art. no. 1124

[1] The oxygen isotope contents (delta(18)O) of soil, xylem, and leaf water and ecosystem respiration were studied in a ponderosa pine forest during summer 2001. Our goal was to assess whether delta(18)O of CO2 could be used to quantify the relative contributions of soil and foliar respiration to total nocturnal ecosystem respiration. The delta(18)O in leaf and soil water showed enrichment over a 2-week sampling period as the weather became hot and dry (leaves 0.9 to 15.0parts per thousand, and soil -10.4 to -3.1parts per thousand), while delta(18)O of xylem water remained constant (-12.9parts per thousand). Water in the soil was enriched in O-18 near the soil surface (-6.4parts per thousand at 5 cm depth) relative to greater depths (-11.1parts per thousand at 20 cm). The delta(18)O of ecosystem respiration became gradually enriched over the 2-week sampling period (from 24.2 initially to 32.9parts per thousand at the end, VSMOW scale). Soil respiration contributed 80 +/- 12 percent to the total respiratory flux, close to estimates from scaled-up chamber data (77% [Law et al., 2001a]). Quantitative application of the isotopic approach to determine respiratory proportions required direct measurement of delta(18)O of soil and xylem water, air and soil temperature, and humidity. Better estimates of the isotopic signatures of component fluxes could be achieved with additional measurements and more detailed modeling. Results demonstrate that (1) there is variability in delta(18)O of precipitation inputs to ecosystems, (2) immediately following a precipitation event, delta(18)O of ecosystem respiration may reflect delta(18)O of precipitation, (3) periods of hot dry weather can substantially enrich ecosystem water pools and subsequently alter the isotope content of CO2 in ecosystem respiration, and (4) stable oxygen isotopes in CO2 can be used to quantify the foliar and soil components of ecosystem respiration.