Stefania Mambelli1, Kevin P. Tu1, Alexander Knohl2, Siyan Ma1, Dennis D. Baldocchi1, and Todd E. Dawson1. (1) University of California, (2) Max Planck Institute for Biogeochemistry
Blue oak savannas are exposed to broad variation in water availability and to severe droughts during the summer months.
Previous findings from instantaneous gas exchange measurements showed that very large oaks maintain constant water-use
efficiency (WUE; carbon fixed per water lost) even in the face of very dry summers. Here, we expanded upon these results and
investigated the influence of tree size using a more integrated index of WUE, the stable carbon isotope composition (δ13C) of
leaf soluble carbohydrates. Trees that varied in diameter (at breast height, ranging from 0.2 to 0.7m) were sampled during the
summer drought (June-September) in two subsequent years. Preliminary results showed large differences among trees in δ13C
of leaf soluble carbohydrates (from -24‰ to -28‰), but each tree's δ13C remained relatively constant over time. This indicated
that intrinsic WUE (ratio of carbon assimilation to stomatal conductance to water loss) was also constant, despite decreasing soil
water content and leaf water potentials. Differences among trees could not be explained by either tree size or differential use of soil
water sources (estimated by δ18O of soil and xylem water). Leaf-level, isotope based WUE estimates on individual trees were
compared with ecosystem-level WUE estimates derived from continuous eddy covariance measurements of water and carbon
exchange. These comparisons indicate that these savanna trees cope with severe drought conditions through coordinated
down-regulation of carbon and water fluxes. Our findings improve our understanding of the manner by which trees in extremely dry
environments can respond to drought.