Identifying drivers of leaf water and cellulose stable isotope enrichment in Eucalyptus in northern Australia

Several previous studies have investigated the use of the stable hydrogen and oxygen isotope compositions in plant materials as indicators of palaeoclimate. However, accurate interpretation relies on a detailed understanding of both physiological and environmental drivers of the variations in isotop...

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Veröffentlicht in:	Oecologia 2017-01, Vol.183 (1), p.31-43
Hauptverfasser:	Munksgaard, N. C., Cheesman, A. W., English, N. B., Zwart, C., Kahmen, A., Cernusak, L. A.
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Schlagworte:	Australia Biomedical and Life Sciences Cellulose Ecology Eucalyptus Growing season Hydrology/Water Resources Isotopic enrichment Leaves Life Sciences Organic compounds Oxygen Isotopes Paleoclimate PHYSIOLOGICAL ECOLOGY - ORIGINAL RESEARCH Plant Leaves Plant Sciences Stable isotopes Vapor pressure Water Water vapor
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description	Several previous studies have investigated the use of the stable hydrogen and oxygen isotope compositions in plant materials as indicators of palaeoclimate. However, accurate interpretation relies on a detailed understanding of both physiological and environmental drivers of the variations in isotopic enrichments that occur in leaf water and associated organic compounds. To progress this aim we measured δ¹⁸O and δ²H values in eucalypt leaf and stem water and δ¹⁸O values in leaf cellulose, along with the isotopic compositions of water vapour, across a north-eastern Australian aridity gradient. Here we compare observed leaf water enrichment, along with previously published enrichment data from a similar north Australian transect, to Craig–Gordon-modelled predictions of leaf water isotopic enrichment. Our investigation of model parameters shows that observed ¹⁸O enrichment across the aridity gradients is dominated by the relationship between atmospheric and internal leaf water vapour pressure while ²H enrichment is driven mainly by variation in the water vapour—source water isotopic disequilibrium. During exceptionally dry and hot conditions (RH < 21%, T > 37 °C) we observed strong deviations from Craig– Gordon predicted isotope enrichments caused by partial stomatal closure. The atmospheric–leaf vapour pressure relationship is also a strong predictor of the observed leaf cellulose δ¹⁸O values across one aridity gradient. Our finding supports a wider applicability of leaf cellulose δ¹⁸O composition as a climate proxy for atmospheric humidity conditions during the leaf growing season than previously documented.
doi_str_mv	10.1007/s00442-016-3761-8
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Here we compare observed leaf water enrichment, along with previously published enrichment data from a similar north Australian transect, to Craig–Gordon-modelled predictions of leaf water isotopic enrichment. Our investigation of model parameters shows that observed ¹⁸O enrichment across the aridity gradients is dominated by the relationship between atmospheric and internal leaf water vapour pressure while ²H enrichment is driven mainly by variation in the water vapour—source water isotopic disequilibrium. During exceptionally dry and hot conditions (RH < 21%, T > 37 °C) we observed strong deviations from Craig– Gordon predicted isotope enrichments caused by partial stomatal closure. The atmospheric–leaf vapour pressure relationship is also a strong predictor of the observed leaf cellulose δ¹⁸O values across one aridity gradient. 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The atmospheric–leaf vapour pressure relationship is also a strong predictor of the observed leaf cellulose δ¹⁸O values across one aridity gradient. 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subjects	Australia Biomedical and Life Sciences Cellulose Ecology Eucalyptus Growing season Hydrology/Water Resources Isotopic enrichment Leaves Life Sciences Organic compounds Oxygen Isotopes Paleoclimate PHYSIOLOGICAL ECOLOGY - ORIGINAL RESEARCH Plant Leaves Plant Sciences Stable isotopes Vapor pressure Water Water vapor
title	Identifying drivers of leaf water and cellulose stable isotope enrichment in Eucalyptus in northern Australia
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