Articles | Volume 8, issue 11
Biogeosciences, 8, 3375–3389, 2011

Special issue: Understanding the impacts of hydrological changes on terrestrial...

Biogeosciences, 8, 3375–3389, 2011

Research article 18 Nov 2011

Research article | 18 Nov 2011

Nonlinear controls on evapotranspiration in arctic coastal wetlands

A. K. Liljedahl1,2, L. D. Hinzman1, Y. Harazono1,3, D. Zona4,8, C. E. Tweedie5, R. D. Hollister6, R. Engstrom7, and W. C. Oechel8 A. K. Liljedahl et al.
  • 1International Arctic Research Center, University of Alaska Fairbanks, Fairbanks, AK-99775, USA
  • 2Water and Environmental Research Center, University of Alaska Fairbanks, Fairbanks, AK-99775, USA
  • 3Osaka Prefecture University, Sakai, Osaka-599-8531, Japan
  • 4Research Group of Plant and Vegetation Ecology, University of Antwerp, B-2610 Wilrijk, Belgium
  • 5Department of Biology, University of Texas at El Paso, El Paso, TX-79968, USA
  • 6Department of Biology, Grand Valley State University, Allendale, MI-49401, USA
  • 7Department of Geography, The George Washington University, Washington, DC-20052, USA
  • 8Department of Biology, San Diego State University, San Diego, CA-92182, USA

Abstract. Projected increases in air temperature and precipitation due to climate change in Arctic wetlands could dramatically affect ecosystem function. As a consequence, it is important to define controls on evapotranspiration, the major pathway of water loss from these systems. We quantified the multi-year controls on midday Arctic coastal wetland evapotranspiration, measured with the eddy covariance method at two vegetated, drained thaw lake basins near Barrow, Alaska. Variations in near-surface soil moisture and atmospheric vapor pressure deficits were found to have nonlinear effects on midday evapotranspiration rates. Vapor pressure deficits (VPD) near 0.3 kPa appeared to be an important hydrological threshold, allowing latent heat flux to persistently exceed sensible heat flux. Dry (compared to wet) soils increased bulk surface resistance (water-limited). Wet soils favored ground heat flux and therefore limited the energy available to sensible and latent heat flux (energy-limited). Thus, midday evapotranspiration was suppressed from both dry and wet soils but through different mechanisms. We also found that wet soils (ponding excluded) combined with large VPD, resulted in an increased bulk surface resistance and therefore suppressing evapotranspiration below its potential rate (Priestley-Taylor α < 1.26). This was likely caused by the limited ability of mosses to transfer moisture during large atmospheric demands. Ultimately, in addition to net radiation, the various controlling factors on midday evapotranspiration (i.e., near-surface soil moisture, atmospheric vapor pressure, and the limited ability of saturated mosses to transfer water during high VPD) resulted in an average evapotranspiration rate of up to 75% of the potential evapotranspiration rate. These multiple limitations on midday evapotranspiration rates have the potential to moderate interannual variation of total evapotranspiration and reduce excessive water loss in a warmer climate. Combined with the prevailing maritime winds and projected increases in precipitation, these curbing mechanisms will likely prevent extensive future soil drying and hence maintain the presence of coastal wetlands.

Final-revised paper