Soil moisture storage estimation based on steady vertical fluxes under equilibrium

•We extended Vertical Equilibrium Model (VEM0) to consider steady state fluxes (VEMF).•Water content difference between VEM0 and VEMF (Wdiff) was quantified.•Wdiff was significant for some soil types and higher net vertical flux rates.•Wdiff was negligible for a case study with shallow water table l...

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Veröffentlicht in:	Journal of hydrology (Amsterdam) 2017-10, Vol.553, p.798-804
Hauptverfasser:	Amvrosiadi, Nino, Bishop, Kevin, Seibert, Jan
Format:	Artikel
Sprache:	eng
Schlagworte:	catchment Catchment hydrology Catchment water storage Catchments Digital storage equilibrium Equilibrium approaches estimation method Evapotranspiration flux measurement Groundwater hillslope hypothesis testing infiltration Moisture moisture content Oceanografi, hydrologi, vattenresurser Oceanography, Hydrology, Water Resources Physically based models Runoff Soil moisture Soil testing soil texture soil water Soil water content Soil water storage Soils VEM Vertical equilibriums Vertical flux Vertical fluxes volume Volumetric soil water content Water content Water storage Water supply water table
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container_title	Journal of hydrology (Amsterdam)
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creator	Amvrosiadi, Nino Bishop, Kevin Seibert, Jan
description	•We extended Vertical Equilibrium Model (VEM0) to consider steady state fluxes (VEMF).•Water content difference between VEM0 and VEMF (Wdiff) was quantified.•Wdiff was significant for some soil types and higher net vertical flux rates.•Wdiff was negligible for a case study with shallow water table levels. Soil moisture is an important variable for hillslope and catchment hydrology. There are various computational methods to estimate soil moisture and their complexity varies greatly: from one box with vertically constant volumetric soil water content to fully saturated-unsaturated coupled physically-based models. Different complexity levels are applicable depending on the simulation scale, computational time limitations, input data and knowledge about the parameters. The Vertical Equilibrium Model (VEM) is a simple approach to estimate the catchment-wide soil water storage at a daily time-scale on the basis of water table level observations, soil properties and an assumption of hydrological equilibrium without vertical fluxes above the water table. In this study VEM was extended by considering vertical fluxes, which allows conditions with evaporation and infiltration to be represented. The aim was to test the hypothesis that the simulated volumetric soil water content significantly depends on vertical fluxes. The water content difference between the no-flux, equilibrium approach and the new constant-flux approach greatly depended on the soil textural class, ranging between ∼1% for silty clay and ∼44% for sand at an evapotranspiration rate of 5mm·d−1. The two approaches gave a mean volumetric soil water content difference of ∼1mm for two case studies (sandy loam and organic rich soils). The results showed that for many soil types the differences in estimated storage between the no-flux and the constant flux approaches were relatively small.
doi_str_mv	10.1016/j.jhydrol.2017.08.042
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Soil moisture is an important variable for hillslope and catchment hydrology. There are various computational methods to estimate soil moisture and their complexity varies greatly: from one box with vertically constant volumetric soil water content to fully saturated-unsaturated coupled physically-based models. Different complexity levels are applicable depending on the simulation scale, computational time limitations, input data and knowledge about the parameters. The Vertical Equilibrium Model (VEM) is a simple approach to estimate the catchment-wide soil water storage at a daily time-scale on the basis of water table level observations, soil properties and an assumption of hydrological equilibrium without vertical fluxes above the water table. In this study VEM was extended by considering vertical fluxes, which allows conditions with evaporation and infiltration to be represented. The aim was to test the hypothesis that the simulated volumetric soil water content significantly depends on vertical fluxes. The water content difference between the no-flux, equilibrium approach and the new constant-flux approach greatly depended on the soil textural class, ranging between ∼1% for silty clay and ∼44% for sand at an evapotranspiration rate of 5mm·d−1. The two approaches gave a mean volumetric soil water content difference of ∼1mm for two case studies (sandy loam and organic rich soils). 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Soil moisture is an important variable for hillslope and catchment hydrology. There are various computational methods to estimate soil moisture and their complexity varies greatly: from one box with vertically constant volumetric soil water content to fully saturated-unsaturated coupled physically-based models. Different complexity levels are applicable depending on the simulation scale, computational time limitations, input data and knowledge about the parameters. The Vertical Equilibrium Model (VEM) is a simple approach to estimate the catchment-wide soil water storage at a daily time-scale on the basis of water table level observations, soil properties and an assumption of hydrological equilibrium without vertical fluxes above the water table. In this study VEM was extended by considering vertical fluxes, which allows conditions with evaporation and infiltration to be represented. The aim was to test the hypothesis that the simulated volumetric soil water content significantly depends on vertical fluxes. The water content difference between the no-flux, equilibrium approach and the new constant-flux approach greatly depended on the soil textural class, ranging between ∼1% for silty clay and ∼44% for sand at an evapotranspiration rate of 5mm·d−1. The two approaches gave a mean volumetric soil water content difference of ∼1mm for two case studies (sandy loam and organic rich soils). 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Bishop, Kevin ; Seibert, Jan</author></sort><facets><frbrtype>5</frbrtype><frbrgroupid>cdi_FETCH-LOGICAL-a479t-9a6738c78b3ddc44e897a2c2541f26826497cdd1072cb57ac8191fd480c2554d3</frbrgroupid><rsrctype>articles</rsrctype><prefilter>articles</prefilter><language>eng</language><creationdate>2017</creationdate><topic>catchment</topic><topic>Catchment hydrology</topic><topic>Catchment water storage</topic><topic>Catchments</topic><topic>Digital storage</topic><topic>equilibrium</topic><topic>Equilibrium approaches</topic><topic>estimation method</topic><topic>Evapotranspiration</topic><topic>flux measurement</topic><topic>Groundwater</topic><topic>hillslope</topic><topic>hypothesis testing</topic><topic>infiltration</topic><topic>Moisture</topic><topic>moisture content</topic><topic>Oceanografi, hydrologi, vattenresurser</topic><topic>Oceanography, Hydrology, Water Resources</topic><topic>Physically based models</topic><topic>Runoff</topic><topic>Soil moisture</topic><topic>Soil testing</topic><topic>soil texture</topic><topic>soil water</topic><topic>Soil water content</topic><topic>Soil water storage</topic><topic>Soils</topic><topic>VEM</topic><topic>Vertical equilibriums</topic><topic>Vertical flux</topic><topic>Vertical fluxes</topic><topic>volume</topic><topic>Volumetric soil water content</topic><topic>Water content</topic><topic>Water storage</topic><topic>Water supply</topic><topic>water table</topic><toplevel>peer_reviewed</toplevel><toplevel>online_resources</toplevel><creatorcontrib>Amvrosiadi, Nino</creatorcontrib><creatorcontrib>Bishop, Kevin</creatorcontrib><creatorcontrib>Seibert, Jan</creatorcontrib><creatorcontrib>Sveriges lantbruksuniversitet</creatorcontrib><collection>CrossRef</collection><collection>SwePub</collection><collection>SwePub Articles</collection><collection>SWEPUB Uppsala universitet</collection><jtitle>Journal of hydrology (Amsterdam)</jtitle></facets><delivery><delcategory>Remote Search Resource</delcategory><fulltext>fulltext</fulltext></delivery><addata><au>Amvrosiadi, Nino</au><au>Bishop, Kevin</au><au>Seibert, Jan</au><aucorp>Sveriges lantbruksuniversitet</aucorp><format>journal</format><genre>article</genre><ristype>JOUR</ristype><atitle>Soil moisture storage estimation based on steady vertical fluxes under equilibrium</atitle><jtitle>Journal of hydrology (Amsterdam)</jtitle><date>2017-10-01</date><risdate>2017</risdate><volume>553</volume><spage>798</spage><epage>804</epage><pages>798-804</pages><issn>0022-1694</issn><issn>1879-2707</issn><eissn>1879-2707</eissn><abstract>•We extended Vertical Equilibrium Model (VEM0) to consider steady state fluxes (VEMF).•Water content difference between VEM0 and VEMF (Wdiff) was quantified.•Wdiff was significant for some soil types and higher net vertical flux rates.•Wdiff was negligible for a case study with shallow water table levels. Soil moisture is an important variable for hillslope and catchment hydrology. There are various computational methods to estimate soil moisture and their complexity varies greatly: from one box with vertically constant volumetric soil water content to fully saturated-unsaturated coupled physically-based models. Different complexity levels are applicable depending on the simulation scale, computational time limitations, input data and knowledge about the parameters. The Vertical Equilibrium Model (VEM) is a simple approach to estimate the catchment-wide soil water storage at a daily time-scale on the basis of water table level observations, soil properties and an assumption of hydrological equilibrium without vertical fluxes above the water table. In this study VEM was extended by considering vertical fluxes, which allows conditions with evaporation and infiltration to be represented. The aim was to test the hypothesis that the simulated volumetric soil water content significantly depends on vertical fluxes. The water content difference between the no-flux, equilibrium approach and the new constant-flux approach greatly depended on the soil textural class, ranging between ∼1% for silty clay and ∼44% for sand at an evapotranspiration rate of 5mm·d−1. The two approaches gave a mean volumetric soil water content difference of ∼1mm for two case studies (sandy loam and organic rich soils). The results showed that for many soil types the differences in estimated storage between the no-flux and the constant flux approaches were relatively small.</abstract><pub>Elsevier B.V</pub><doi>10.1016/j.jhydrol.2017.08.042</doi><tpages>7</tpages><orcidid>https://orcid.org/0000-0003-2662-9264</orcidid></addata></record>
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subjects	catchment Catchment hydrology Catchment water storage Catchments Digital storage equilibrium Equilibrium approaches estimation method Evapotranspiration flux measurement Groundwater hillslope hypothesis testing infiltration Moisture moisture content Oceanografi, hydrologi, vattenresurser Oceanography, Hydrology, Water Resources Physically based models Runoff Soil moisture Soil testing soil texture soil water Soil water content Soil water storage Soils VEM Vertical equilibriums Vertical flux Vertical fluxes volume Volumetric soil water content Water content Water storage Water supply water table
title	Soil moisture storage estimation based on steady vertical fluxes under equilibrium
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