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References Adams, H. D., M. Guardiola-Claramonte, G. A. Barron-Gafford, J. C. Villegas, D. D. Breshears, C. B. Zoug, et al. 2009. Temperature sensitivity of drought-induced tree mortality: implications for regional die-off under global change type drought. Proc. Natl Acad. Sci. USA 106:70637066. Allen, C. D., and D. D. Breshears. 1998. Drought induced shift of a forest woodland ecotone: rapid landscape responses to climate variation. Proc. Natl Acad. Sci. USA 95:1483914842. Allen, C. D., A. K. Macalady, H. Chenschouni, D. Bachelet, N. McDowell, M. Vennetier, et al. 2010. A global overview of drought and heat-induced tree mortality reveals emerging climate change risks for forests. For. Ecol. Manage. 259:660684. Bannerman, S. M., and P. A. Hazelton. 1990. P. 122 in Soil landscapes of the Penrith 1:100 000 sheet (Map and Report). Soil Conservation Service of NSW, Sydney. Barton, C. V. M., R.A. Duursma, B. E. Medlyn, D. S. Ellsowrth, D. Eamus, D. T. Tissue, et al. 2011. Effects of elevated atmospheric [CO2] on instantaneous transpiration efficiency at leaf and canopy scales in Eucalyptus saligna. Glob. Change Biol. 18:585595. Breshears, D. D., N. S. Cobb, P. M. Rich, K. P. Price, C. D. Allen, R. G. Balice, et al. 2005. Regional vegetation die-off in response to global-change type drought. Proc. Natl Acad. Sci. USA 95:1514415148. Breshears, D. D., O. B. Myers, C. W. Meyers, F. J. Barnes, C. B. Zou, C. D. Allen, et al. 2009. Tree die-off in response to global change-type drought: mortality insights from a decade of plant water potential measurements. Front. Ecol. Environ. 7:185189. Breshears, D. D., L. López-Hoffman, and L. J. Graumlich. 2011. When ecosystem services crash: preparing for big, fast, patchy climate change. Ambio 40:256263. Chen, X., L. B. Hutley, and D. Eamus. 2003. Carbon balance of a tropical savanna of Australia. Oecologia 137:405416. Dai, A. 2011. Drought under global warming: a review. Wiley Interdiscip. Rev. Clim. Change 2:4565. Davis, L. G., K. Muehlenbachs, C. E. Schweger, and N. W. Rutter. 2002. Differential response of vegetation to postglacial climate in the Lower Salmon River Canyon, Idaho. Palaeogeogr. Palaeoclimatol. Palaeoecol. 185:339354. Easterling, D. R., B. H. Horton, P. D. Jones, T. C. Peterson, T. R. Karl, D. E. Parker, et al. 1997. Maximum and minimum temperature trends for the globe. Science 277:364367. Farquhar, G. D., and S. von Caemmerer. 1982. Modelling of photosynthetic response to the environment. Pp. 549587 in O. L. Lange, P. S. Nobel, C. B. Osmond, H. Ziegler, eds. Physiological plant ecology II. Encyclopedia of plant physiology. New Series Vol. 12B. Springer-Verlag, Berlin. Fisher, R. A., M. Willimas, A. L. Da Costa, Y. Malhi, R. F. Da Costa, S. Almeida, et al. 2007. The response of an Eastern Amazonian rain forest to drought stress: results and modelling analyses from a throughfall exclusion experiment. Glob. Change Biol. 13:118. Ghannoum, O., J. R. Evans, W. S. Chow, T. J. Andrews, J. P. Conroy, and S. von Caemmerer. 2005. Faster Rubisco is the key to superior nitrogen use efficiency in grasses. Plant Physiol. 137:638650. Horner, G. J., P. J. Baker, R. MacNally, S. C. Cunningham, J. R. Thomson, and F. Hamilton. 2009. Mortality of developing floodplain forests subjected to a drying climate and water extraction. Glob. Change Biol. 15:21762186. IPCC. 2011. Managing the risks of extreme events and disasters to advance climate change adaptation (SREX). Cambridge University Press, Cambridge, U.K. Jentsch, A., J. Kreyling, and C. Beierkuhniein. 2007. A new generation of climate change experiments: events not trends. Front. Ecol. Environ. 5:365374. Kelley, G., A. P. O'Grady, L. B. Hutley, and D. Eamus. 2007. A comparison of tree water used in two contiguous vegetation communities of the seasonally dry tropics of northern Australia. Aust. J. Bot. 55:700708. Kumagai, T., and A. Porporato. 2012. Drought induced mortality of a Bornean tropical rain forest amplified by climate change. J. Geophy. Res. 117. doi: 10.1029/2011JG001835. Labate, C. A., M. D. Adcock, and R. C. Leegood. 1990. Effect of temperature on photosynthetic carbon assimilation and contents of photosynthetic intermediates in leaves of maize and barley. Planta 181:547554. Leuzinger, S., C. Bigler, A. Wolf, and C. Korner. 2009. Poor methodology for predicting large-scale tree die-off. Proc. Natl Acad. Sci. USA, 106:E106. doi: 10.1073/PNAS 0908053106 Macinnis-Ng, C., M. Zeppel, M. Williams, and D. Eamus. 2010. Applying a SPA model to examine the impact of climate change on GPP of open woodlands and the potential for woody thickening. Ecohydrology 4:379393. van Mantgem, P. J., N. L. Stephenson, J. C. Byrne, L. D. Daniels, J. F. Franklin, P. Z. Fule, et al. 2009. Widespread increase in tree mortality rate in the western United States. Science 323:521524. Matsoukas, C., N. Benas, N. Hatzianastassiou, K. G. Paviakis, and I. Vardavas. 2011. Potential evaporation trends over land surface between 1983–2008: driven by radiative fluxes or vapour pressure deficit? Atmos. Chem. Phys. 11:76017616. McDowell, N., W. T. Pockman, C. D. Allen, D. D. Breshears, N. Cobb, T. Kolb, et al. 2008. Mechanisms of plant survival and mortality during drought: why do some plants survive while others succumb to drought? New Phytol. 178:719739. McDowell, N. G., D. J. Beerling, D. D. Breshears, R. A. Fisher, K. F. Raffa, and M. Stitt. 2011. The interdependence of mechanisms underlying climate-driven vegetation mortality. Trends Ecol. Evol. 26:523532. Meehl, G. A., C. Tebaldi, G. Walton, D. Easterling, and L. McDaniel. 2009. Relative increase of record high maximum temperatures compared to record low minimum temperatures in the US. Geophy. Res. Lett. 36. doi: 10.1029/2009GL040736. Overpeck, J. T., and J. E. Cole. 2006. Abrupt change in the Earth's climate system. Annu. Rev. Environ. Resour. 31:131. Overpeck, J., and B. Udall. 2010. Dry times ahead. Science 328:16421643. Prior, L. D., D. Eamus and G. A. Duff. 1997. Seasonal trends in carbon assimilation, stomatal conductance, pre-dawn leaf water potential and growth in Terminalia ferdinandiana a deciduous tree of northern Australia. Australian Journal of Botany 45:5369. Prior, L. D., D. M. J. S. Bowman, and D. Eamus. 2004. Seasonal differences leaf attributes in Australian tropical tree species: family and habitat comparisons. Functional Ecol. 18:707718. Sala, A., F. Piper, and G. Hoch. 2010. Physiological mechanisms of drought-induced tree mortality are far from being resolved. New Phytol. 186:274281. Smith, M. 2011. An ecological perspective on extreme climatic events: a synthetic definition and framework to guide future research. J. Ecol. 99:656663. Tardieu, F., and T. Simmoneau. 1998. Variability among species of stomatal control under fluctuating soil water status and evaporative demand. Modelling isohydric and anisohydric behaviours. J. Exp. Bot. 49:419432. Weiss, J. L., C. L. Castro, and J. T. Overpeck. 2009. Distinguishing pronounced droughts in the SW USA: seasonality and effects of warmer temperatures. J. Clim. 22:5932. Weiss, J. L., J. L. Betancourt, and J. T. Overpeck. 2012. Climatic limits on foliar growth during major droughts in the southwestern USA. J. Geophys. Res. 117:G03031. Whitley, R. J., C. M. O. Macinnis-Ng, L. B. Hutley, J. Berringer, M. Zeppel, M. Williams, et al. 2011. Is productivity of mesic savannas light limited or water limited? Results of a simulation study. Glob Change Biol. 17:31303149. Williams, M., E. B. Rastetter, and D. N. Fernandes. 1996. Modelling the soil-plant-atmosphere continuum in a Quercus-Acer stand at Harvard Forest: the regulation of stomata conductance by light, nitrogen and soil/plant hydraulic properties. Plant Cell Environ. 19:911927. Williams, M., Y. Malhi, A. Nobre, E. Rastetter, J. Grace, and M. Pereira. 1998. Seasonal variation in net carbon exchange and evapotranspiration in a Brazilliam rain forest. Plant Cell Environ. 21:953968. Williams, M., B. E. Law, P. M. Anthoni, and M. H. Unsworth. 2001. Use of a simulation model and ecosystem flux data to examine carbon–water interactions in ponderosa pine. Tree Physiol. 21:287298. Williams, M., F. I. Woodward, D. D. Baldocchi, and D. Ellsworth. 2004. CO2 capture from the leaf to the landscape. Pp. 130 in W. K. Smith, T. C. Vogelmann, C. Critchley, eds. Photosynthetic adaptation: chloroplast to landscape. Ecological Studies 178. Springer, Berlin. Williams, M., T. C. Hill, and C. M. Ryan. 2012. Using biomass distributions to determine probability and intensity of tropical forest disturbance. Plant Ecol. Divers. 6:113. Zeppel, M. J., C. Macinnis-Ng, A. Palmer, D. Taylor, R. Whitley, S. Fuentes, et al. 2008. An analysis of the sensitivity of sap flux to soil and plant variables assessed for an Australian woodland using a soil-plant-atmosphere model. Funct. Plant Biol. 35:509520. Zhang, Y., R. Leuning, F. H. S. Chiew, E. Wang, L. Zhang, C. Liu, et al. 2012. Decadal trends in evaporation from global energy and water balances. J. Hydrometeorol. 13:379391.
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© 2013. This work is published under http://creativecommons.org/licenses/by/3.0/ (the “License”). Notwithstanding the ProQuest Terms and Conditions, you may use this content in accordance with the terms of the License.

Abstract

Drought-induced tree mortality is occurring across all forested continents and is expected to increase worldwide during the coming century. Regional-scale forest die-off influences terrestrial albedo, carbon and water budgets, and land-surface energy partitioning. Although increased temperatures during drought are widely identified as a critical contributor to exacerbated tree mortality associated with “global-change-type drought”, corresponding changes in vapor pressure deficit (D) have rarely been considered explicitly and have not been disaggregated from that of temperature per se. Here, we apply a detailed mechanistic soil–plant–atmosphere model to examine the impacts of drought, increased air temperature (+2°C or +5°C), and increased vapor pressure deficit (D; +1 kPa or +2.5 kPa), singly and in combination, on net primary productivity (NPP) and transpiration and forest responses, especially soil moisture content, leaf water potential, and stomatal conductance. We show that increased D exerts a larger detrimental effect on transpiration and NPP, than increased temperature alone, with or without the imposition of a 3-month drought. Combined with drought, the effect of increased D on NPP was substantially larger than that of drought plus increased temperature. Thus, the number of days when NPP was zero across the 2-year simulation was 13 or 14 days in the control and increased temperature scenarios, but increased to approximately 200 days when D was increased. Drought alone increased the number of days of zero NPP to 88, but drought plus increased temperature did not increase the number of days. In contrast, drought and increased D resulted in the number of days when NPP = 0 increasing to 235 (+1 kPa) or 304 days (+2.5 kPa). We conclude that correct identification of the causes of global change-type mortality events requires explicit consideration of the influence of D as well as its interaction with drought and temperature.

Details

Title
Global change-type drought-induced tree mortality: vapor pressure deficit is more important than temperature per se in causing decline in tree health
Author
Eamus, Derek 1 ; Boulain, Nicolas 2 ; Cleverly, James 2 ; Breshears, David D 3 

 Plant Biology and Climate Change Research Cluster, University of Technology Sydney, Sydney, New South Wales, Australia; National Centre for Groundwater Research and Training, University of Technology Sydney, Sydney, New South Wales, Australia 
 Plant Biology and Climate Change Research Cluster, University of Technology Sydney, Sydney, New South Wales, Australia 
 School of Natural Resources and the Environment, University of Arizona, Tucson, Arizona; Department of Ecology and Evolutionary Biology, University of Arizona, Tucson, Arizona 
Pages
2711-2729
Section
Original Research
Publication year
2013
Publication date
Aug 2013
Publisher
John Wiley & Sons, Inc.
e-ISSN
20457758
Source type
Scholarly Journal
Language of publication
English
DOI
https://doi.org/10.1002/ece3.664
ProQuest document ID
2290323562
Copyright
© 2013. This work is published under http://creativecommons.org/licenses/by/3.0/ (the “License”). Notwithstanding the ProQuest Terms and Conditions, you may use this content in accordance with the terms of the License.