Temporal dynamics of oxygen isotope compositions of soil and canopy CO2 fluxes in a temperate deciduous forest

Partitioning of CO2 exchange into canopy (FA) and soil (FR) flux components is essential to improve our understanding of ecosystem processes. The stable isotope C18OO can be used for flux partitioning, but this approach depends on the magnitude and consistency of the isotope disequilibrium (Deq), i....

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Bibliographic Details
Published in:Journal of geophysical research. Biogeosciences 2014-05, Vol.119 (5), p.996-1013
Main Authors: Santos, E., Wagner-Riddle, C., Lee, X., Warland, J., Brown, S., Staebler, R., Bartlett, P., Kim, K.
Format: Article
Language:English
Subjects:
Canopies
Carbon dioxide
Deciduous forests
ecosystem
Fluctuations
Growing season
Hydration
Isotopes
Leaves
Mixed forests
Moisture content
Oxygen isotopes
Soil water
Stable isotopes
Studies
temperate deciduous forest
Temperate forests
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Summary:Partitioning of CO2 exchange into canopy (FA) and soil (FR) flux components is essential to improve our understanding of ecosystem processes. The stable isotope C18OO can be used for flux partitioning, but this approach depends on the magnitude and consistency of the isotope disequilibrium (Deq), i.e., the difference between the isotope compositions of FR (δA) and FA (δR). In this study, high temporal resolution isotopic data were used (1) to test the suitability of existing steady state and nonsteady models to estimate H218O enrichment in a mixed forest canopy, (2) to investigate the temporal dynamics of δA using a big‐leaf parameterization, and (3) to quantify the magnitude of the C18OO disequilibrium (Deq) in a temperate deciduous forest throughout the growing season and to determine the sensitivity of this variable to the CO2 hydration efficiency (θeq). A departure from steady state conditions was observed even at midday in this study, so the nonsteady state formulation provided better estimates of leaf water isotope composition. The dynamics of δR was mainly driven by changes in soil water isotope composition, caused by precipitation events. Large Deq values (up to 11‰) were predicted; however, the magnitude of the disequilibrium was variable throughout the season. The magnitude of Deq was also very sensitive to the hydration efficiencies in the canopy. For this temperate forest during most of the growing season, the magnitude of Deq was inversely proportional to θeq, due to the very negative δR signal, which is contrary to observations for other ecosystems investigated in previous studies. Key Points Large isotope disequilibrium was predicted at the site Models captured the dynamics leaf water isotope composition Precipitation was the main driver of the dynamics of flux isotope signatures
ISSN:2169-8953
2169-8961
DOI:10.1002/2013JG002525