Abstract
Increasing vapor pressure deficit (VPD) increases atmospheric demand for water. While increased evapotranspiration (ET) in response to increased atmospheric demand seems intuitive, plants are capable of reducing ET in response to increased VPD by closing their stomata. We examine which effect dominates the response to increasing VPD: atmospheric demand and increases in ET or plant response (stomata closure) and decreases in ET. We use Penman‐Monteith, combined with semiempirical optimal stomatal regulation theory and underlying water use efficiency, to develop a theoretical framework for assessing ET response to VPD. The theory suggests that depending on the environment and plant characteristics, ET response to increasing VPD can vary from strongly decreasing to increasing, highlighting the diversity of plant water regulation strategies. The ET response varies due to (1) climate, with tropical and temperate climates more likely to exhibit a positive ET response to increasing VPD than boreal and arctic climates; (2) photosynthesis strategy, with C3 plants more likely to exhibit a positive ET response than C4 plants; and (3) plant type, with crops more likely to exhibit a positive ET response, and shrubs and gymniosperm trees more likely to exhibit a negative ET response. These results, derived from previous literature connecting plant parameters to plant and climate characteristics, highlight the utility of our simplified framework for understanding complex land‐atmosphere systems in terms of idealized scenarios in which ET responds to VPD only. This response is otherwise challenging to assess in an environment where many processes coevolve together.
Highlights
Vapor pressure deficit (VPD) is expected to rise over continents in the future due to the combination of increased temperature and, depending on region, decreased relative humidity (Byrne & O’Gorman, 2013)
Higher g 1 and underlying Water Use Efficiency (uWUE) shift the curve towards increasing ET responses with VPD, and smaller g 1 values lead to a larger VPD dependence of the response (i.e. ET response is a stronger function of VPD)
We derived a new form of Penman Monteith using the concept of semi-empirical optimal stomatal regulation
Summary
Vapor pressure deficit (VPD) is expected to rise over continents in the future due to the combination of increased temperature and, depending on region, decreased relative humidity (Byrne & O’Gorman, 2013). Increases in VPD increase the atmospheric demand for evapotranspirated water (Penman, 1948; Monteith et al, 1965), and reduce stomatal conductance through stomatal closure (Rawson et al, 1977; Leuning, 1990; Mott, 2007; Damour et al, 2010; Medlyn et al, 2011). The opposing effects of increased atmospheric demand and higher stomatal closure lead to two possible perspectives for how ET responds to shifts in VPD. G. Katul et al, 2009; Medlyn et al, 2011) This leads to a plant physiology perspective, in which an increase in VPD may correspond to a decrease in ET because of stomatal closure The question “When does VPD drive or reduce ET?” can be related to whether plant regulation or atmospheric demand dominates the ET response
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