2022 ESA Annual Meeting (August 14 - 19)

COS 239-3 A shift from light-limited to water-limited sap velocity in the Central Amazon during an extreme drought

10:30 AM-10:45 AM
516A
Lin Meng, Lawrence Berkeley National Laboratory;Jeffrey Chambers,Lawrence Berkeley National Laboratory;Charles Koven,Lawrence Berkeley National Lab;Gilberto Pastorello,Lawrence Berkeley National Laboratory;Bruno Gimenez,National Institute of Amazonian Research (INPA);Kolby Jardine,Lawrence Berkeley National Laboratory;Yao Tang,Lawrence Berkeley National Laboratory;Nate G. McDowell,Pacific Northwest National Laboratory;Robinson Negron-Juarez,Lawrence Berkeley National Laboratory;Marcos Longo,Lawrence Berkeley National Laboratory;Alessandro Araújo,Brazilian Agricultural Research Corporation (Embrapa);Javier Tomasella,Centro Nacional de Monitoramento e Alertas de Desastres Naturais - CEMADEN;Clarissa Fontes,University of California, Berkeley;Mikey Mohan,University of California, Berkeley;Niro Higuchi,National Institute of Amazonian Research (INPA);
Background/Question/Methods

Transpiration in tropical forests plays a critical role in regulating the global water cycle and climate. Transpiration is often considered to be light- but not water-limited in humid tropical rainforests due to abundant soil water, even during the dry seasons. As the climate becomes warmer and drier, it is more likely that a threshold could be reached after which soil moisture, instead of light availability, becomes a primary regulator of transpiration. The record-breaking 2015-16 El Niño drought provided a unique opportunity to examine whether transpiration is constrained by water under severe lack of rainfall. We measured sap velocity, soil water content, and meteorological variables in an old-growth upland forest in the Central Amazon throughout the 2015-16 drought.

Results/Conclusions

We found a rapid decline in sap velocity and in its temporal variability during the drought compared to the regular dry season. Such changes were accompanied by a marked decline in soil moisture and an increase in temperature and vapor pressure deficit. Sap velocity was largely limited by net radiation during the wet season; however, it shifted to be primarily limited by soil moisture during the drought. The threshold in which sap velocity became dominated by soil moisture was at 0.33 m3/m3 (around -150 kPa in soil matric potential), below which sap velocity dropped steeply. Our study provides evidence for a soil water threshold on transpiration in a moist tropical forest, suggesting a shift from light limitation to water limitation under future climate characterized by increased temperature and an increased frequency, intensity, duration and extent of extreme drought events. The ability of tropical forests in the Amazon to survive in the future largely depends on their acclimation and adaptation to drier conditions.