Browsing BC3 Journal Articles by Author "Ellsworth, D.S."

Now showing items 1-5 of 5

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      Elevated CO2 did not affect the hydrological balance of a mature native Eucalyptus woodland 

      Gimeno, T.E.; McVicar, T.R.; O'Grady, A.P.; Tissue, D.T.; Ellsworth, D.S. (John Wiley and Sons, 2018)
      Elevated atmospheric CO2 concentration (eCa) might reduce forest water-use, due to decreased transpiration, following partial stomatal closure, thus enhancing water-use efficiency and productivity at low water availability. ...
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      Incorporating non-stomatal limitation improves the performance of leaf and canopy models at high vapour pressure deficit 

      Yang, J.; Duursma, R.A.; De Kauwe, M.G.; Kumarathunge, D; Jiang, M; Mahmud, K; Gimeno, T.E.; Crous, K.Y.; Ellsworth, D.S.; Peters, J; Choat, B; Eamus, D; Medlyn, B.E. (Oxford University Press, 2019)
      Vapour pressure deficit (D) is projected to increase in the future as temperature rises. In response to increased D, stomatal conductance (gs) and photosynthesis (A) are reduced, which may result in significant reductions ...
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      Low sensitivity of gross primary production to elevated CO2 in a mature eucalypt woodland 

      Yang, J.; Medlyn, B.E.; De, Kauwe, M.G.; Duursma, R.A.; Jiang, M.; Kumarathunge, D.; Crous, K.Y.; Gimeno, T.E.; Wujeska-Klause, A.; Ellsworth, D.S. (EGU Publications, 2020)
      The response of mature forest ecosystems to a rising atmospheric carbon dioxide concentration (span classCombining double low line"inline-formula"iC/ia/span) is a major uncertainty in projecting the future trajectory of ...
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      Optimal stomatal theory predicts CO<inf>2</inf> responses of stomatal conductance in both gymnosperm and angiosperm trees 

      Gardner, A.; Jiang, M.; Ellsworth, D.S.; MacKenzie, A.R.; Pritchard, J.; Bader, M.K.F.; Barton, C.V.M.; Bernacchi, C.; Calfapietra, C.; Crous, K.Y.; Dusenge, M.E.; Gimeno, T.E.; Hall, M.; Lamba, S.; Leuzinger, S.; Uddling, J.; Warren, J.; Wallin, G.; Medlyn, B.E. (New Phytologist, 2023)
      Optimal stomatal theory predicts that stomata operate to maximise photosynthesis (Anet) and minimise transpirational water loss to achieve optimal intrinsic water-use efficiency (iWUE). We tested whether this theory can ...
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      The fate of carbon in a mature forest under carbon dioxide enrichment 

      Jiang, M.; Medlyn, B.E.; Drake, J.E.; Duursma, R.A.; Anderson, I.C.; Barton, C.V.M.; Boer, M.M.; Carrillo, Y.; Castañeda-Gómez, L.; Collins, L.; Crous, K.Y.; De Kauwe, M.G.; Dos Santos, B.M.; Emmerson, K.M.; Facey, S.L.; Gherlenda, A.N.; Gimeno, T.E.; Hasegawa, S.; Johnson, S.N.; Kännaste, A.; Macdonald, C.A.; Mahmud, K.; Moore, B.D.; Nazaries, L.; Neilson, E.H.J.; Nielsen, U.N.; Niinemets, Ü.; Noh, N.J.; Ochoa-Hueso, R.; Pathare, V.S.; Pendall, E.; Pihlblad, J.; Piñeiro, J.; Powell, J.R.; Power, S.A.; Reich, P.B.; Renchon, A.A.; Riegler, M.; Rinnan, R.; Rymer, P.D.; Salomón, R.L.; Singh, B.K.; Smith, B.; Tjoelker, M.G.; Walker, J.K.M.; Wujeska-Klause, A.; Yang, J.; Zaehle, S.; Ellsworth, D.S. (Springer Nature, 2020)
      Atmospheric carbon dioxide enrichment (eCO2) can enhance plant carbon uptake and growth1 5, thereby providing an important negative feedback to climate change by slowing the rate of increase of the atmospheric CO2 ...