Vapor Flow Resistance of Dry Soil Layer to Soil Water Evaporation in Arid Environment: An Overview

Vapor Flow Resistance of Dry Soil Layer to Soil Water Evaporation in Arid Environment: An Overview

Evaporation from bare sandy soils is the core component of the hydrologic cycle in arid environments, where vertical water movement dominates. Although extensive measurement and modeling studies have been conducted and reported in existing literature, the physics of dry soil and its function in evap...

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Main Author: Xixi Wang
Format: Article
Language:English
Published: MDPI AG 2015-08-01
Series:Water
Subjects:
Condensation
water content
PdV model
sandy soils
sensors
vaporization
Online Access:http://www.mdpi.com/2073-4441/7/8/4552
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spelling doaj-e77e860ea687475492c73a670b0fec462020-11-24T20:47:04ZengMDPI AGWater2073-44412015-08-01784552457410.3390/w7084552w7084552Vapor Flow Resistance of Dry Soil Layer to Soil Water Evaporation in Arid Environment: An OverviewXixi Wang0Department of Civil and Environmental Engineering, Old Dominion University, Norfolk, VA 23529-0241, USAEvaporation from bare sandy soils is the core component of the hydrologic cycle in arid environments, where vertical water movement dominates. Although extensive measurement and modeling studies have been conducted and reported in existing literature, the physics of dry soil and its function in evaporation is still a challenging topic with significant remaining issues. Thus, an overview of the previous findings will be very beneficial for identifying further research needs that aim to advance our understanding of the vapor flow resistance (VFR) effect on soil water evaporation as influenced by characteristics of the dry soil layer (DSL) and evaporation zone (EZ). In this regard, six measurement and four modeling studies were overviewed. The results of these overviewed studies, along with the others, affirm the conceptual dynamics of DSL and EZ during drying or wetting processes (but not both) within dry sandy soils. The VFR effect tends to linearly increase with DSL thickness (δ) when δ < 5 cm and is likely to increase as a logarithmic function of δ when δ ≥ 5 cm. The vaporization-condensation-movement (VCM) dynamics in a DSL depend on soil textures: sandy soils can form a thick (10 to 20 cm) DSL while sandy clay soils may or may not have a clear DSL; regardless, a DSL can function as a transient EZ, a vapor condensation zone, and/or a vapor transport medium. Based on the overview, further studies will need to generate long-term continuous field data, develop hydraulic functions for very dry soils, and establish an approach to quantify the dynamics and VFR effects of DSLs during wetting-drying cycles as well as take into account such effects  when using conventional (e.g., Penman-Monteith) evaporation models.http://www.mdpi.com/2073-4441/7/8/4552Condensationwater contentPdV modelsandy soilssensorsvaporization
collection DOAJ
language English
format Article
sources DOAJ
author Xixi Wang
spellingShingle Xixi Wang
Vapor Flow Resistance of Dry Soil Layer to Soil Water Evaporation in Arid Environment: An Overview
Water
Condensation
water content
PdV model
sandy soils
sensors
vaporization
author_facet Xixi Wang
author_sort Xixi Wang
title Vapor Flow Resistance of Dry Soil Layer to Soil Water Evaporation in Arid Environment: An Overview
title_short Vapor Flow Resistance of Dry Soil Layer to Soil Water Evaporation in Arid Environment: An Overview
title_full Vapor Flow Resistance of Dry Soil Layer to Soil Water Evaporation in Arid Environment: An Overview
title_fullStr Vapor Flow Resistance of Dry Soil Layer to Soil Water Evaporation in Arid Environment: An Overview
title_full_unstemmed Vapor Flow Resistance of Dry Soil Layer to Soil Water Evaporation in Arid Environment: An Overview
title_sort vapor flow resistance of dry soil layer to soil water evaporation in arid environment: an overview
publisher MDPI AG
series Water
issn 2073-4441
publishDate 2015-08-01
description Evaporation from bare sandy soils is the core component of the hydrologic cycle in arid environments, where vertical water movement dominates. Although extensive measurement and modeling studies have been conducted and reported in existing literature, the physics of dry soil and its function in evaporation is still a challenging topic with significant remaining issues. Thus, an overview of the previous findings will be very beneficial for identifying further research needs that aim to advance our understanding of the vapor flow resistance (VFR) effect on soil water evaporation as influenced by characteristics of the dry soil layer (DSL) and evaporation zone (EZ). In this regard, six measurement and four modeling studies were overviewed. The results of these overviewed studies, along with the others, affirm the conceptual dynamics of DSL and EZ during drying or wetting processes (but not both) within dry sandy soils. The VFR effect tends to linearly increase with DSL thickness (δ) when δ < 5 cm and is likely to increase as a logarithmic function of δ when δ ≥ 5 cm. The vaporization-condensation-movement (VCM) dynamics in a DSL depend on soil textures: sandy soils can form a thick (10 to 20 cm) DSL while sandy clay soils may or may not have a clear DSL; regardless, a DSL can function as a transient EZ, a vapor condensation zone, and/or a vapor transport medium. Based on the overview, further studies will need to generate long-term continuous field data, develop hydraulic functions for very dry soils, and establish an approach to quantify the dynamics and VFR effects of DSLs during wetting-drying cycles as well as take into account such effects  when using conventional (e.g., Penman-Monteith) evaporation models.
topic Condensation
water content
PdV model
sandy soils
sensors
vaporization
url http://www.mdpi.com/2073-4441/7/8/4552
work_keys_str_mv AT xixiwang vaporflowresistanceofdrysoillayertosoilwaterevaporationinaridenvironmentanoverview
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