Evapotranspiration across plant types and geomorphological units in polygonal Arctic tundra

Coastal tundra ecosystems are relatively flat, and yet display large spatial variability in ecosystem traits. The microtopographical differences in polygonal geomorphology produce heterogeneity in permafrost depth, soil temperature, soil moisture, soil geochemistry, and plant distribution. Few measu...

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Main Authors:	Raz-Yaseef, N, Young-Robertson, J, Rahn, T, Sloan, V, Newman, B, Wilson, C, Wullschleger, SD, Torn, MS
Format:	Article in Journal/Newspaper
Language:	unknown
Published:	eScholarship, University of California 2017
Subjects:	Arctic tundra Evapotranspiration Greenhouse gases Moss Polygon structure Environmental Engineering Arctic Barrow permafrost Tundra Alaska
Online Access:	https://escholarship.org/uc/item/4d1322c5

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spelling	ftcdlib:oai:escholarship.org/ark:/13030/qt4d1322c5 2023-05-15T14:56:34+02:00 Evapotranspiration across plant types and geomorphological units in polygonal Arctic tundra Raz-Yaseef, N Young-Robertson, J Rahn, T Sloan, V Newman, B Wilson, C Wullschleger, SD Torn, MS 2017-10-01 application/pdf https://escholarship.org/uc/item/4d1322c5 unknown eScholarship, University of California qt4d1322c5 https://escholarship.org/uc/item/4d1322c5 public Arctic tundra Evapotranspiration Greenhouse gases Moss Polygon structure Environmental Engineering article 2017 ftcdlib 2021-06-28T17:07:24Z Coastal tundra ecosystems are relatively flat, and yet display large spatial variability in ecosystem traits. The microtopographical differences in polygonal geomorphology produce heterogeneity in permafrost depth, soil temperature, soil moisture, soil geochemistry, and plant distribution. Few measurements have been made, however, of how water fluxes vary across polygonal tundra plant types, limiting our ability to understand and model these ecosystems. Our objective was to investigate how plant distribution and geomorphological location affect actual evapotranspiration (ET). These effects are especially critical in light of the rapid change polygonal tundra systems are experiencing with Arctic warming. At a field site near Barrow, Alaska, USA, we investigated the relationships between ET and plant cover in 2014 and 2015. ET was measured at a range of spatial and temporal scales using: (1) An eddy covariance flux tower for continuous landscape-scale monitoring; (2) An automated clear surface chamber over dry vegetation in a fixed location for continuous plot-scale monitoring; and (3) Manual measurements with a clear portable chamber in approximately 60 locations across the landscape. We found that variation in environmental conditions and plant community composition, driven by microtopographical features, has significant influence on ET. Among plant types, ET from moss-covered and inundated areas was more than twice that from other plant types. ET from troughs and low polygonal centers was significantly higher than from high polygonal centers. ET varied seasonally, with peak fluxes of 0.14 mm h−1 in July. Despite 24 hours of daylight in summer, diurnal fluctuations in incoming solar radiation and plant processes produced a diurnal cycle in ET. Combining the patterns we observed with projections for the impact of permafrost degradation on polygonal structure suggests that microtopographic changes associated with permafrost thaw have the potential to alter tundra ecosystem ET. Article in Journal/Newspaper Arctic Barrow permafrost Tundra Alaska University of California: eScholarship Arctic
institution	Open Polar
collection	University of California: eScholarship
op_collection_id	ftcdlib
language	unknown
topic	Arctic tundra Evapotranspiration Greenhouse gases Moss Polygon structure Environmental Engineering
spellingShingle	Arctic tundra Evapotranspiration Greenhouse gases Moss Polygon structure Environmental Engineering Raz-Yaseef, N Young-Robertson, J Rahn, T Sloan, V Newman, B Wilson, C Wullschleger, SD Torn, MS Evapotranspiration across plant types and geomorphological units in polygonal Arctic tundra
topic_facet	Arctic tundra Evapotranspiration Greenhouse gases Moss Polygon structure Environmental Engineering
description	Coastal tundra ecosystems are relatively flat, and yet display large spatial variability in ecosystem traits. The microtopographical differences in polygonal geomorphology produce heterogeneity in permafrost depth, soil temperature, soil moisture, soil geochemistry, and plant distribution. Few measurements have been made, however, of how water fluxes vary across polygonal tundra plant types, limiting our ability to understand and model these ecosystems. Our objective was to investigate how plant distribution and geomorphological location affect actual evapotranspiration (ET). These effects are especially critical in light of the rapid change polygonal tundra systems are experiencing with Arctic warming. At a field site near Barrow, Alaska, USA, we investigated the relationships between ET and plant cover in 2014 and 2015. ET was measured at a range of spatial and temporal scales using: (1) An eddy covariance flux tower for continuous landscape-scale monitoring; (2) An automated clear surface chamber over dry vegetation in a fixed location for continuous plot-scale monitoring; and (3) Manual measurements with a clear portable chamber in approximately 60 locations across the landscape. We found that variation in environmental conditions and plant community composition, driven by microtopographical features, has significant influence on ET. Among plant types, ET from moss-covered and inundated areas was more than twice that from other plant types. ET from troughs and low polygonal centers was significantly higher than from high polygonal centers. ET varied seasonally, with peak fluxes of 0.14 mm h−1 in July. Despite 24 hours of daylight in summer, diurnal fluctuations in incoming solar radiation and plant processes produced a diurnal cycle in ET. Combining the patterns we observed with projections for the impact of permafrost degradation on polygonal structure suggests that microtopographic changes associated with permafrost thaw have the potential to alter tundra ecosystem ET.
format	Article in Journal/Newspaper
author	Raz-Yaseef, N Young-Robertson, J Rahn, T Sloan, V Newman, B Wilson, C Wullschleger, SD Torn, MS
author_facet	Raz-Yaseef, N Young-Robertson, J Rahn, T Sloan, V Newman, B Wilson, C Wullschleger, SD Torn, MS
author_sort	Raz-Yaseef, N
title	Evapotranspiration across plant types and geomorphological units in polygonal Arctic tundra
title_short	Evapotranspiration across plant types and geomorphological units in polygonal Arctic tundra
title_full	Evapotranspiration across plant types and geomorphological units in polygonal Arctic tundra
title_fullStr	Evapotranspiration across plant types and geomorphological units in polygonal Arctic tundra
title_full_unstemmed	Evapotranspiration across plant types and geomorphological units in polygonal Arctic tundra
title_sort	evapotranspiration across plant types and geomorphological units in polygonal arctic tundra
publisher	eScholarship, University of California
publishDate	2017
url	https://escholarship.org/uc/item/4d1322c5
geographic	Arctic
geographic_facet	Arctic
genre	Arctic Barrow permafrost Tundra Alaska
genre_facet	Arctic Barrow permafrost Tundra Alaska
op_relation	qt4d1322c5 https://escholarship.org/uc/item/4d1322c5
op_rights	public
_version_	1766328662082191360

Evapotranspiration across plant types and geomorphological units in polygonal Arctic tundra

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