2017 ESA Annual Meeting (August 6 -- 11)

COS 79-2 - In the heat of the moment: Diurnal patterns of branch carbon uptake and transpiration during heat waves

Wednesday, August 9, 2017: 8:20 AM
B118-119, Oregon Convention Center
Alexandria Pivovaroff1, Alejandra Pequeira2, Wu Sun2 and Ulrike Seibt2, (1)La Kretz Center for California Conservation Science, UCLA, Los Angeles, CA, (2)UCLA
Background/Question/Methods

Mediterranean-type ecosystems are biodiversity hotspots, but increasing temperature and changes in precipitation will have significant impacts on vegetation, as evidenced by the recent die-back of many woody species in southern California, USA, due to exceptional drought conditions. We installed flow-through chambers on four native woody plant species at Stunt Ranch, a University of California Natural Reserve System site, in order to continuously monitor fluxes of carbon and water at the branch-scale from the growing season through the annual seasonal drought period. Study species included Heteromeles arbutifolia, Malosma laurina, Quercus agrifolia, and Quercus berberidifolia. Here we present the results of diurnal flux patterns before, during, and after extreme heat waves events, when daily maximum temperatures doubled.

Results/Conclusions

Under typical summer conditions, which include hot, sunny days, study species exhibited two peaks in carbon assimilation during a diurnal cycle: a peak in the morning and a smaller, secondary peak in the afternoon, separated by a midday depression. During heat wave events, which generally lasted 3 days, species exhibited a small morning peak and no afternoon peak at all. All study species returned to their pre-heat wave diurnal flux patterns, which included the second afternoon peak, when weather conditions returned to normal. Since soil moisture was not affected by the short-term heat wave events, we conclude that the pronounced changes in diurnal patterns, including disappearance of the secondary afternoon peak, are the result of stomatal regulation in response to atmospheric water demand rather than root responses to soil moisture deficits. Our results demonstrate that carbon uptake of native species may be impacted under ongoing climate change when heat waves and drought conditions may become more frequent and persistent.