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REFERENCES

  • Adams M.A. & Grierson P.F. (2001) Stable isotopes at natural abundance in terrestrial plant ecology and ecophysiology: An update. Plant Biology 0, 299310.
  • Baldocchi D.D., Matt D.R., Hutchison B.A. & McMillen R.T. (1984) Solar radiation within an oak-hickory forest: An evaluation of the extinction coefficients for several radiation components during fully-leafed and leafless periods. Agricultural and Forest Meteorology 32, 307322.
  • Barbour M.M., Schurr U., Henry B.K., Wong S.C. & Farquhar G.D. (2000a) Variation in the oxygen isotope ratio of phloem sap sucrose from castor bean. Evidence in support of the Peclet effect. Plant Physiology 123, 671679.
  • Barbour M.M., Fischer R.A., Sayre K.D. & Farquhar G.D. (2000b) Oxygen isotope ratio of leaf and grain material correlates with stomatal conductance and yield in irrigated, field-grown wheat. Australian Journal of Plant Physiology 27, 625637.
  • Barbour M.M., Walcroft A.S. & Farquhar G.D. (2002) Seasonal variation in δ13C and δ18O of cellulose from growths rings of Pinus radiata. Plant, Cell and Environment 25, 14831499.
  • Breda N., Granier A. & Aussenac G. (1995) Effects of thinning on soil and tree water relations, transpiration and growths in an oak forest (Quercus petrea (Matt.) Liebl.). Tree Physiology 15, 295306.
  • Brendel O. (2001) Does bulk needle δ13C reflect short-term discrimination? Annals of Forest Science 58, 135141.
  • Damesin C., Rambal S. & Joffre R. (1998) Seasonal drought and annual changes in leaf δ13C in two co-occurring Mediterranean oaks: relations to leaf growth and drought progression. Functional Ecology 12, 778785.
  • DeNiro M.J. & Epstein S. (1979) Relationship between oxygen isotope ratios of terrestrial plant cellulose, carbon dioxide and water. Science 204, 5153.
  • Dongmann G., Nürnberg H.W., Förstel H. & Wagner K. (1974) On the enrichment of H218O in the leaves of transpiring plants. Radiation and Environmental Biophysics 11, 4152.
  • Dupouey J.S., Leavitt S.W., Choisnel E. & Jourdain S. (1993) Modelling carbon isotope fractionation in tree rings based on effective evapotranspiration and soil water status. Plant, Cell and Environment 16, 939947.
  • Farquhar G.D., Barbour N.M. & Henry B.K. (1998) Interpretation of oxygen isotope composition of leaf material. In Stable Isotopes – Integration of Biological, Ecological, and Geochemical Processes (ed. H.Griffiths), pp. 2762. BIOS. Scientific Publishers, Oxford, UK.
  • Farquhar G.D., Ehleringer J.R. & Hubick K.T. (1989) Carbon isotope discrimination and photosynthesis. In Annual Review of Plant Physiology and Plant Molecular Biology (ed. W.R.Briggs), pp. 503538. Annual Reviews Inc., Palo Alto, CA, USA.
  • Farquhar G.D., O'Leary M.H. & Berry J.A. (1982) On the relationship between carbon isotope discrimination and the intercellular carbon dioxide concentration in leaves. Australian Journal of Plant Physiology 9, 121137.
  • Fotelli M.N., Nahm M., Heidenfelder A., Papen H., Rennenberg H. & Geßler A. (2002) Soluble nonprotein nitrogen compounds indicate changes in the nitrogen status of beech seedlings due to climate and thinning. New Phytologist 154 (0), 8597.
  • Fritsch J. (1998) Energiebilanz und Verdunstung eines bewaldeten Hanges im Hochschwarzwald. PhD Thesis. Bericht Des Meteorologischen Instituts der Universität Freiburg.
  • Geßler A., Schrempp S., Matzarakis A., Mayer H., Rennenberg H. & Adams M.A. (2001) Radiation modifies the effect of water availability on the carbon isotope composition of beech (Fagus sylvatica L.). New Phytologist 50, 653664.
  • Glavac V., Koenis H., Jochheim H. & Ebben U. (1989) Mineralstoffe im Xylemsaft der Buche und ihre jahreszeitlichen Konzentrationsveränderungen entlang der Stammhöhe. Angewandte Botanik 63, 471486.
  • Granier A. (1985) Une nouvelle méthode pour la mesure du flux de sève brute dans le tronc des arbres. Annales Sciences Forestiers 42, 8188.
  • Granier A., Biron P., Koestner B., Gay L.W. & Najjar G. (1996) Comparisons of xylem sap flow and water vapour flux at the stand level and derivation of canopy conductance for Scots pine. Theoretical and Applied Climatology 53, 115122.
  • Guehl J.-M., Fort C. & Ferhi A. (1995) Differential response of leaf conductance, carbon isotope discrimination and water-use efficiency to nitrogen deficiency in maritime pine and pedunculate oak plants. New Phytologist 131, 149157.
  • Högberg P., Johannisson C. & Hällgren J.-E. (1993) Studies of 13C in the foliage reveal interactions between nutrients and water in fertilization experiments. Plant and Soil 152, 207214.
  • Holst T.H., Matzarakis A., Mayer H., Rost J. & Schindler D. (2001) Mikroklima in Buchenbeständen auf gegenüberliegenden Hängen in der Schwäbischen Alb. In Beitrag zur 1. Deutsch-Österreichisch-Schweizerischen Meteorologentagung Wien, September 2001, Österreich. Beiträge Meteorologie Geophysik 27, 118.
  • Hultine K.R. & Marshall J.D. (2000) Altitude trends in conifer leaf morphology and stable carbon isotope composition. Oecologia 123, 3240.
  • Jones H.G. (1998) Stomatal control of photosynthesis and transpiration. Journal of Experimental Botany 49 (special issue), 387398.
  • Korol R.L., Kirschbaum M.U.F., Farquhar G.D. & Jeffreys M. (1999) Effects of water status and soil fertility on the C-isotope signature in Pinus radiata. Tree Physiology 19, 551562.
  • Köstner B., Biron P., Siegwolf R. & Granier A. (1996) Estimates of water vapor flux and canopy conductance of Scots pine at the tree level utilizing different xylem sap flow methods. Theoretical and Applied Climatology 5, 105113.
  • Kozlowski T.T. & Pallardy S.G. (1997) Physiology of Woody Plants 2nd edn, 411 pp. Academic Press, San Diego, CA, USA.
  • Kull O., Broadmeadow M., Kruijt B. & Meir P. (1999) Light distribution and foliage structure in an oak canopy. Trees 14, 5564.
  • Lauteri M., Scartazza A., Guido M.C. & Brugnoli E. (1997) Genetic variation in photosynthetic capacity, carbon isotope discrimination and mesophyll conductance in provenances of Castanea sativa adapted to different environments. Functional Ecology 11, 675683.
  • Leavitt S.W. & Long A. (1986) Stable-carbon isotope variability in tree foliage and wood. Ecology 67, 10021010.
  • Livingston N.J. & Spittlehouse D.L. (1996) Carbon isotope fractionation in tree ring early and late wood in relation to intra-season water balance. Plant, Cell and Environment 19, 768774.
  • Macfarlane C. & Adams M.A. (1998) δ13C of wood in growth-rings indicates cambial activity in drought-stressed trees of Eucalyptus globulus. Functional Ecology 12, 655664.
  • Matzarakis A., Mayer H., Schindler D. & Fritsch J. (2000) Simulation des Wasserhaushaltes eines Buchenwaldes mit dem forstlichen Wasserhaushaltsmodell WBS3. Bericht Des Meteorologischen Instituts der Universität Freiburg 5, 137146.
  • Millard P. (1996) Ecophysiology of internal cycling of nitrogen for Tree Growth. Zeitschrift für Pflanzenernährung und Bodenkunde 159, 110.
  • Oberdorfer E. (1992) Süddeutsche Pflanzengesellschaften Teil IV: Wälder und Gebüsche. Fischer-Verlag, Stuttgart, Germany.
  • Pataki D.E., Oren R. & Phillips N. (1998) Responses of sap flux and stomatal conductance of Pinus taeda L. Trees to stepwise reductions in leaf area. Journal of Experimental Botany 49, 871878.
  • Pate J.S. & Arthur D. (1998) δ13C analysis of phloem sap carbon: novel means of evaluating seasonal water stress and interpreting carbon isotope signatures of foliage and trunk wood of Eucalyptus globulus. Oecologia 117, 301311.
  • Pate J., Shedley E., Arthur D. & Adams M.A. (1998) Spatial and temporal variations in phloem sap composition of plantation-grown Eucalyptus globulus. Oecologia 117, 312322.
  • Roden J.S. & Ehleringer J.R. (1999a) Hydrogen and oxygen isotope ratios of tree-ring cellulose for riparian trees grown long-term under hydroponically controlled environments. Oecologia 121 (4), 467477.
  • Roden J.S. & Ehleringer J.R. (1999b) Observations of hydrogen and oxygen isotopes in leaf water confirm the Craig-Gordon model under wide-ranging environmental conditions. Plant Physiology 120 (4), 11651173.
  • Scheidegger Y., Saurer M., Bahn M. & Siegwolf R. (2000) Linking stable oxygen and carbon isotopes with stomatal conductance and photosynthetic capacity: a conceptual model. Oecologia 125 (3), 350357.
  • Schmidt H.-L. & Gleixner G. (1998) Carbon isotope effects on key reactions in plant metabolism and 13C patterns in natural compounds. In Stable Isotopes – Integration of Biological, Ecological, and Geochemical Processes (ed. H.Griffiths), pp. 1325. BIOS Scientific Publishers, Oxford, UK.
  • Sternberg L., Mulkey S.S. & Wright S.J. (1989) Oxygen isotope ratio stratification in a tropical moist forest. Oecologia 81, 5156.
  • Walcroft A.S., Silvester W.B., Grace J.C., Carson S.D. & Waring R.H. (1996) Effects of branch length on carbon isotope discrimination in Pinus radiata. Tree Physiology 16, 281286.
  • Warren C.R. & Adams M.A. (2000) Water availability and branch length determine δ13C in foliage of Pinus pinaster. Tree Physiology 20, 637643.
  • Warren C.R., McGrath J. & Adams M.A. (2001) Water availability and carbon isotope discrimination in conifers. Oecologia 127, 476486.
  • Whitehead D. & Jarvis P.G. (1981) Coniferous forests and Plantations. In Water Deficits and Plant Growth (ed. T.T.Kozlowski) Vol. VI, pp. 4952. Academic Press, San Diego, CA, USA.
  • Xu Z.H., Saffigna P.G., Farquhar G.D., Simpson J.A., Haines R.J., Walker S., Osborne D.O. & Guinto D. (2000) Carbon isotope discrimination and oxygen isotope composition in clones of the F1 hybrid between slash pine and Caribbean pine in relation to tree growth, water-use efficiency and foliar nutrient concentration. Tree Physiology 20 (18), 12091217.
  • Yakir D. (1992) Variations in the natural abundance of oxygen-18 and deuterium in plant carbohydrates. Plant, Cell and Environment 15 (9), 10051020.
  • Yang X., Miller D.R. & Montgomery M.E. (1993) Vertical distributions of canopy foliage and biologically active radiation in a defoliated/refoliated hardwood forest. Agricultural and Forest Meteorology 67, 129146.
  • Yoneyama T., Handley L.L., Scrimgeour C.M., Fisher D.B. & Raven J.A. (1997) Variations of the natural abundances of nitrogen and carbon isotopes in Triticum aestivum, with special reference to phloem and xylem exudates. New Phytologist 137, 205213.
  • Zimmermann M.H. & Braun C.L. (1971) Trees, Structure and Function. Springer, Berlin, Germany.