A dynamic physical model for soil temperature and water in Taylor Valley, Antarctica

We developed a simulation model for terrestrial sites including sensible heat exchange between the atmosphere and ground surface, inter- and intra-layer heat conduction by rock and soil, and shortwave and longwave radiation. Water fluxes included snowmelt, freezing/thawing of soil water, soil capill...

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Bibliographic Details
Main Authors: H.W. Hunt, A.G. Fountain, P.T. Doran, H. Basagic
Format: Other Non-Article Part of Journal/Newspaper
Language:unknown
Published: 2010
Subjects:
Uncategorized
untagged
Taylor Valley
Antarc*
Antarctica
Online Access:http://hdl.handle.net/10027/8511
https://figshare.com/articles/journal_contribution/A_dynamic_physical_model_for_soil_temperature_and_water_in_Taylor_Valley_Antarctica/10768100
id ftuillchicagofig:oai:figshare.com:article/10768100
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spelling ftuillchicagofig:oai:figshare.com:article/10768100 2023-05-15T13:45:27+02:00 A dynamic physical model for soil temperature and water in Taylor Valley, Antarctica H.W. Hunt A.G. Fountain P.T. Doran H. Basagic 2010-08-01T00:00:00Z http://hdl.handle.net/10027/8511 https://figshare.com/articles/journal_contribution/A_dynamic_physical_model_for_soil_temperature_and_water_in_Taylor_Valley_Antarctica/10768100 unknown http://hdl.handle.net/10027/8511 https://figshare.com/articles/journal_contribution/A_dynamic_physical_model_for_soil_temperature_and_water_in_Taylor_Valley_Antarctica/10768100 In Copyright Uncategorized untagged Text Journal contribution 2010 ftuillchicagofig 2022-11-19T07:37:42Z We developed a simulation model for terrestrial sites including sensible heat exchange between the atmosphere and ground surface, inter- and intra-layer heat conduction by rock and soil, and shortwave and longwave radiation. Water fluxes included snowmelt, freezing/thawing of soil water, soil capillary flow, and vapour flows among atmosphere, soil, and snow. The model accounted for 96–99% of variation in soil temperature data. No long-term temporal trends in soil temperature were apparent. Soil water vapour concentration in thawed surface soil in summer often was higher than in frozen deeper soils, leading to downward vapour fluxes. Katabatic winds caused a reversal of the usual winter pattern of upward vapour fluxes. The model exhibited a steady state depth distribution of soil water due to vapour flows and in the absence of capillary flows below the top 0.5 cm soil layer. Beginning with a completely saturated soil profile, soil water was lost rapidly, and within a few hundred years approached a steady state characterized by dry soil (,0.5% gravimetric) down to one metre depth and saturated soil below that. In contrast, it took 42 000 years to approach steady state beginning from a completely dry initial condition. Other Non-Article Part of Journal/Newspaper Antarc* Antarctica Indigo - University of Illinois at Chicago Taylor Valley ENVELOPE(163.000,163.000,-77.617,-77.617)
institution Open Polar
collection Indigo - University of Illinois at Chicago
op_collection_id ftuillchicagofig
language unknown
topic Uncategorized
untagged
spellingShingle Uncategorized
untagged
H.W. Hunt
A.G. Fountain
P.T. Doran
H. Basagic
A dynamic physical model for soil temperature and water in Taylor Valley, Antarctica
topic_facet Uncategorized
untagged
description We developed a simulation model for terrestrial sites including sensible heat exchange between the atmosphere and ground surface, inter- and intra-layer heat conduction by rock and soil, and shortwave and longwave radiation. Water fluxes included snowmelt, freezing/thawing of soil water, soil capillary flow, and vapour flows among atmosphere, soil, and snow. The model accounted for 96–99% of variation in soil temperature data. No long-term temporal trends in soil temperature were apparent. Soil water vapour concentration in thawed surface soil in summer often was higher than in frozen deeper soils, leading to downward vapour fluxes. Katabatic winds caused a reversal of the usual winter pattern of upward vapour fluxes. The model exhibited a steady state depth distribution of soil water due to vapour flows and in the absence of capillary flows below the top 0.5 cm soil layer. Beginning with a completely saturated soil profile, soil water was lost rapidly, and within a few hundred years approached a steady state characterized by dry soil (,0.5% gravimetric) down to one metre depth and saturated soil below that. In contrast, it took 42 000 years to approach steady state beginning from a completely dry initial condition.
format Other Non-Article Part of Journal/Newspaper
author H.W. Hunt
A.G. Fountain
P.T. Doran
H. Basagic
author_facet H.W. Hunt
A.G. Fountain
P.T. Doran
H. Basagic
author_sort H.W. Hunt
title A dynamic physical model for soil temperature and water in Taylor Valley, Antarctica
title_short A dynamic physical model for soil temperature and water in Taylor Valley, Antarctica
title_full A dynamic physical model for soil temperature and water in Taylor Valley, Antarctica
title_fullStr A dynamic physical model for soil temperature and water in Taylor Valley, Antarctica
title_full_unstemmed A dynamic physical model for soil temperature and water in Taylor Valley, Antarctica
title_sort dynamic physical model for soil temperature and water in taylor valley, antarctica
publishDate 2010
url http://hdl.handle.net/10027/8511
https://figshare.com/articles/journal_contribution/A_dynamic_physical_model_for_soil_temperature_and_water_in_Taylor_Valley_Antarctica/10768100
long_lat ENVELOPE(163.000,163.000,-77.617,-77.617)
geographic Taylor Valley
geographic_facet Taylor Valley
genre Antarc*
Antarctica
genre_facet Antarc*
Antarctica
op_relation http://hdl.handle.net/10027/8511
https://figshare.com/articles/journal_contribution/A_dynamic_physical_model_for_soil_temperature_and_water_in_Taylor_Valley_Antarctica/10768100
op_rights In Copyright
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