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Applying the dual-isotope conceptual model to interpret physiological trends under uncontrolled conditions Public Deposited

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https://ir.library.oregonstate.edu/concern/articles/37720d19s

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  • The inter-relationships among δ¹³C and δ¹⁸O in tree ring cellulose and ring width have the potential to illuminate long-term physiological and environmental information in forest stands that have not been monitored. We examine how within-stand competition and environmental gradients affect ring widths and the stable isotopes of cellulose. We utilize a natural climate gradient across a catchment dominated by Douglas-fir and temporal changes in climate over an 8-year period. We apply a dual-isotope approach to infer physiological response of trees in differing crown dominance classes to temporal and spatial changes in environmental conditions using a qualitative conceptual model of the ¹³C–¹⁸O relationship and by normalizing the data to minimize other variance. The δ¹³C and δ¹⁸O of cellulose were correlated with year-to-year variation in relative humidity and consistent with current isotope theory. Using a qualitative conceptual model of the ¹³C–¹⁸O relationship and physiological knowledge about the species, we interpreted these changes as stomatal conductance responses to evaporative demand. Spatial variance between plots was not strong and seemed related to leaf nitrogen rather than any other environmental variable. Dominant trees responded to environmental gradients more consistently with current isotope theory as compared with other classes within the same stand. We found a correlation of stable isotopes with environmental variables is useful for assessing the impacts of environmental change over short time series and where growth varies only minimally with climate.
  • Keywords: Douglas-fir, water-use efficiency, crown dominance, relative humidity, stable isotopes, tree rings, stomatal conductance
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  • Barnard, H. R., Brooks, J. R., & Bond, B. J. (2012). Applying the dual-isotope conceptual model to interpret physiological trends under uncontrolled conditions. Tree Physiology, 32(10), 1183-1198. doi: 10.1093/treephys/tps078
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  • 32
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  • 10
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  • This work was supported by the Oregon State University Institute for Water and Watersheds, the American Geophysical Union Horton Research Grant, the Ford Foundation Fellowships Office and the U.S. Environmental Protection Agency.
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