Abstract
Evapotranspiration (ET) is a relevant component of the surface moisture budget and is associated with different drivers. The interrelated drivers cause variations at daily to interannual timescales. This study uses structural equation modeling to diagnose the drivers over an ensemble of 45 high-latitude sites, each of which provides at least several years of in situ measurements, including latent heat fluxes derived from eddy covariance flux towers. The sites are grouped by vegetation type (tundra, forest) and the presence or absence of permafrost to determine how the relative importance of different drivers depends on land surface characteristics. Factor analysis is used to quantify the common variance among the variables, while a path analysis procedure is used to assess the independent contributions of different variables. The variability of ET at forest sites generally shows a stronger dependence on relative humidity, while ET at tundra sites is more temperature-limited than moisture-limited. The path analysis shows that ET has a stronger direct correlation with solar radiation than with any other measured variable. Wind speed has the largest independent contribution to ET variability. The independent contribution of solar radiation is smaller because solar radiation also affects ET through various other drivers. The independent contribution of wind speed is especially apparent at forest wetland sites. For both tundra and forest vegetation, temperature loads higher on the first factor when permafrost is present, implying that ET will become less sensitive to temperature as permafrost thaws.
Highlights
The terrestrial surface moisture budget has three main components: precipitation (P), evapotranspiration (ET), and runoff (R)
Net shortwave radiation has the largest correlation with ET and is highly correlated with relative humidity, sensible heat flux, ground heat flux, and net longwave radiation on all timescales
Overall variability in ET at forest sites shows a stronger dependence on relative humidity while ET at tundra sites depends more strongly on air temperature and thermal variables
Summary
The terrestrial surface moisture budget has three main components: precipitation (P), evapotranspiration (ET), and runoff (R). While precipitation is the primary driver of changes in the other two components as well as changes in soil moisture storage, ET is a key determinant of soil moisture, especially in the upper soil layers, over timescales of days to seasons. Rates of ET are affected by other factors in addition to precipitation: incoming radiation and the ground temperature, the dryness of the air, wind speed, vegetation type, and the availability of moisture in the upper soil layers [1,2]. Even high-latitude land areas without permafrost experience a seasonal freeze of the upper soil column, and the duration of the seasonal freeze can exceed six months. Snow cover is a pervasive feature of the high-latitude terrestrial region and a substantial contributor to the lateral discharge (runoff) [6]
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