Covariation of vegetation and climate constrains present and future T/ET variability
Copyright policy )Covariation of vegetation and climate constrains present and future T/ET variability
The reliable partitioning of the terrestrial latent heat flux into evaporation (E) and transpiration (T) is important for linking carbon and water cycles and for better understanding ecosystem functioning at local, regional and global scales. Previous research revealed that the transpiration-to-evapotranspiration ratio (T/ET) is well constrained across ecosystems and is nearly independent of vegetation characteristics and climate. Here we investigated the reasons for such a global constancy in present-day T/ET by jointly analysing observations and process-based model simulations. Using this framework, we also quantified how the ratio T/ET could be influenced by changing climate. For present conditions, we found that the various components of land surface evaporation (bare soil evaporation, below canopy soil evaporation, evaporation from interception), and their respective ratios to plant transpiration, depend largely on local climate and equilibrium vegetation properties. The systematic covariation between local vegetation characteristics and climate, resulted in a globally constrained value of T/ET = ~70 ± 9% for undisturbed ecosystems, nearly independent of specific climate and vegetation attributes. Moreover, changes in precipitation amounts and patterns, increasing air temperatures, atmospheric CO2 concentration, and specific leaf area (the ratio of leaf area per leaf mass) was found to affect T/ET in various manners. However, even extreme changes in the aforementioned factors did not significantly modify T/ET.
Environmental Research Letters, 13 (10)
ISSN:1748-9326
ISSN:1748-9318
- University of Montreal Canada
- Imperial College London United Kingdom
- ETH Zurich Switzerland
- Czech University of Life Sciences Prague Czech Republic
- Environmental Engineering Institute Switzerland
ELEVATED ATMOSPHERIC CO2, 550, SURFACE, LEAF-AREA, Science, QC1-999, Environmental Sciences & Ecology, Environmental technology. Sanitary engineering, ecohydrology, CARBON, modelling, USE EFFICIENCY, ECOSYSTEMS, Meteorology & Atmospheric Sciences, GE1-350, TD1-1066, evapotranspiration partitioning, Science & Technology, T/ET; evapotranspiration partitioning; ecohydrology; modelling; climate change, Physics, Q, TRANSPIRATION, WATER FLUXES, T/ET, FOREST, GLOBAL TERRESTRIAL EVAPOTRANSPIRATION, Environmental sciences, climate change, Physical Sciences, Life Sciences & Biomedicine, Environmental Sciences
ELEVATED ATMOSPHERIC CO2, 550, SURFACE, LEAF-AREA, Science, QC1-999, Environmental Sciences & Ecology, Environmental technology. Sanitary engineering, ecohydrology, CARBON, modelling, USE EFFICIENCY, ECOSYSTEMS, Meteorology & Atmospheric Sciences, GE1-350, TD1-1066, evapotranspiration partitioning, Science & Technology, T/ET; evapotranspiration partitioning; ecohydrology; modelling; climate change, Physics, Q, TRANSPIRATION, WATER FLUXES, T/ET, FOREST, GLOBAL TERRESTRIAL EVAPOTRANSPIRATION, Environmental sciences, climate change, Physical Sciences, Life Sciences & Biomedicine, Environmental Sciences
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