B23H-07
Species-specific intrinsic water use efficiency and its mediation of carbon assimilation during the drought

Tuesday, 15 December 2015: 15:10
2004 (Moscone West)
Koong Yi1, Matthew K Wenzel2, Justin Timothy Maxwell3 and Kimberly A Novick1, (1)Indiana University Bloomington, School of Public and Environmental Affairs, Bloomington, IN, United States, (2)Indiana University Bloomington, Department of Geography, Bloomington, IN, United States, (3)Indiana University Bloomington, Bloomington, IN, United States
Abstract:
Drought is expected to occur more frequently and intensely in the future, and many studies have suggested frequent and intense droughts can significantly alter carbon and water cycling in forest ecosystems, consequently decreasing the ability of forests to assimilate carbon. Predicting the impact of drought on forest ecosystem processes requires an understanding of species-specific responses to drought, especially in eastern US where species composition is highly dynamic. An emerging approach for describing species-specific drought response is to classify the plant water use strategy into isohydric and anisohydric behaviors. Trees utilizing isohydric behavior regulate water potential by closing stomata to reduce water loss during drought conditions, while anisohydric trees allow water potential to drop by sustaining stomatal conductance, but with the risk of hydraulic failure caused by cavitation of xylem tissues. Since catastrophic cavitation occurs infrequently in the relatively wet eastern U.S., we hypothesize that 1) tree growth of isohydric trees will be more limited during the drought than the anisohydric trees due to decreased stomatal conductance, but 2) variation in intrinsic water use efficient (iWUE) during drought in isohydric trees will mediate the effects of drought on carbon assimilation. We will test these hypotheses by 1) analyzing tree-ring chronologies and dendrometer data on productivity, and 2) estimating intrinsic water use efficiency (iWUE) at multiple scales by analyzing gas exchange data for the leaf-level, inter-annual variability of d13C in tree stem cores for the tree-level, and eddy covariance technique for the stand-level. Our study site is the Morgan-Monroe State Forest (Indiana, USA). A 46 m flux tower has been continuously recording the carbon, water and energy fluxes, and tree diameter has been measured every 2 weeks using dendrometers, since 1998. Additional research, including gas exchange measurements performed during the growing seasons of 2011-2013 and tree-ring chronologies collected in 2014 and 2015, enable us to assess the long-term impact of climate on the ecosystem processes at multiple scales. Finally, the severe drought experienced in this region in 2012 will help us evaluate how productivity and iWUE respond to an especially severe drought event.