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Vadose Zone Journal
Volume 5, Issue 2
Original Research

Numerical Analysis of Coupled Water, Vapor, and Heat Transport in the Vadose Zone

Hirotaka Saito

Corresponding Author

E-mail address: hirotaka.saito@ucr.edu

Dep. of Environmental Sciences, Univ. of California, Riverside, CA, 92521

Corresponding author (E-mail address: hirotaka.saito@ucr.edu)Search for more papers by this author
Jiri Šimůnek

Dep. of Environmental Sciences, Univ. of California, Riverside, CA, 92521

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Binayak P. Mohanty

Biological and Agricultural Engineering, Texas A&M Univ., College Station, TX, 77843‐2117

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First published: 01 May 2006
https://doi.org/10.2136/vzj2006.0007
Citations: 36

Abstract

Vapor movement is often an important part in the total water flux in the vadose zone of arid or semiarid regions because the soil moisture is relatively low. The two major objectives of this study were to develop a numerical model in the HYDRUS‐1D code that (i) solves the coupled equations governing liquid water, water vapor, and heat transport, together with the surface water and energy balance, and (ii) provides flexibility in accommodating various types of meteorological information to solve the surface energy balance. The code considers the movement of liquid water and water vapor in the subsurface to be driven by both pressure head and temperature gradients. The heat transport module considers movement of soil heat by conduction, convection of sensible heat by liquid water flow, transfer of latent heat by diffusion of water vapor, and transfer of sensible heat by diffusion of water vapor. The modifications allow a very flexible way of using various types of meteorological information at the soil–atmosphere interface for evaluating the surface water and energy balance. The coupled model was evaluated using field soil temperature and water content data collected at a field site. We demonstrate the use of standard daily meteorological variables in generating diurnal changes in these variables and their subsequent use for calculating continuous changes in water contents and temperatures in the soil profile. Simulated temperatures and water contents were in good agreement with measured values. Analyses of the distributions of the liquid and vapor fluxes vs. depth showed that soil water dynamics are strongly associated with the soil temperature regime.

Number of times cited according to CrossRef: 36

  • Arash Modaresi Rad, Bijan Ghahraman, Abolfazl Mosaedi, Mojtaba Sadegh, A Universal Model of Unsaturated Hydraulic Conductivity With Complementary Adsorptive and Diffusive Process Components, Water Resources Research, 10.1029/2019WR025884, 56, 2, (2020).
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  • Maarten W. Saaltink, Claus Kohfahl, Lidia Molano‐Leno, Analysis of water vapor adsorption in soils by means of a lysimeter and numerical modeling, Vadose Zone Journal, 10.1002/vzj2.20012, 19, 1, (2020).
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  • Tobias K. D. Weber, Michael Finkel, Maria Gonçalves, Harry Vereecken, Efstathios Diamantopoulos, Pedotransfer Function for the Brunswick Soil Hydraulic Property Model and Comparison to the van Genuchten‐Mualem Model, Water Resources Research, 10.1029/2019WR026820, 56, 9, (2020).
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  • Bing Liu, Wenzhi Zhao, Zijuan Wen, Yuting Yang, Xuexiang Chang, Zhaocen Zhu, Rui Si, Hydrochemical Characteristics Jointly Determine the Transport and Cycling of Soil Carbon, Nitrogen, and Phosphorus in an Arid Chinese Wetland, Journal of Geophysical Research: Biogeosciences, 10.1029/2020JG005697, 125, 7, (2020).
    Wiley Online Library
  • Esmaiil Mokari, Manoj K. Shukla, Jirka Šimůnek, Jorge L. Fernandez, Numerical Modeling of Nitrate in a Flood‐Irrigated Pecan Orchard, Soil Science Society of America Journal, 10.2136/sssaj2018.11.0442, 83, 3, (555-564), (2019).
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  • Andre Peters, Sascha C. Iden, Wolfgang Durner, Local Solute Sinks and Sources Cause Erroneous Dispersion Fluxes in Transport Simulations with the Convection–Dispersion Equation, Vadose Zone Journal, 10.2136/vzj2019.06.0064, 18, 1, (2019).
    Wiley Online Library
  • Ernest Léontin Lemoubou, Hervé Thierry Tagne Kamdem, Jean Roger Bogning, Edouard Henri Zefack Tonnang, Thermal, Moisture, and Solute Transport Responses Effects on Unsaturated Soil Hydraulic Parameters Estimation, Water Resources Research, 10.1029/2019WR025542, 55, 12, (11225-11249), (2019).
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  • Shmuel Assouline, Kfir Narkis, Evaporation From Multilayered Heterogeneous Bare Soil Profiles, Water Resources Research, 10.1029/2018WR024560, 55, 7, (5770-5783), (2019).
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  • Yunquan Wang, Olivier Merlin, Gaofeng Zhu, Kun Zhang, A Physically Based Method for Soil Evaporation Estimation by Revisiting the Soil Drying Process, Water Resources Research, 10.1029/2019WR025003, 55, 11, (9092-9110), (2019).
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  • Michael D. Novak, Validity of Assuming Equilibrium Between Liquid Water and Vapor for Simulating Evaporation, Water Resources Research, 10.1029/2019WR025113, 55, 11, (9858-9872), (2019).
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  • Marina Hruška, Christoph Clauser, Rik W. De Doncker, The Effect of Drying around Power Cables on the Vadose Zone Temperature, Vadose Zone Journal, 10.2136/vzj2018.05.0105, 17, 1, (1-15), (2018).
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  • Steffen Merz, Bruce J. Balcom, Razieh Enjilela, Jan Vanderborght, Youri Rothfuss, Harry Vereecken, Andreas Pohlmeier, Magnetic Resonance Monitoring and Numerical Modeling of Soil Moisture during Evaporation, Vadose Zone Journal, 10.2136/vzj2016.10.0099, 17, 1, (1-15), (2018).
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  • J. Dijkema, J.E. Koonce, R.M. Shillito, T.A. Ghezzehei, M. Berli, M.J. Ploeg, M.Th. Genuchten, Water Distribution in an Arid Zone Soil: Numerical Analysis of Data from a Large Weighing Lysimeter, Vadose Zone Journal, 10.2136/vzj2017.01.0035, 17, 1, (1-17), (2017).
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  • T.A. Engda, T.J. Kelleners, G.B. Paige, Soil Water Monitoring and Numerical Flow Modeling to Quantify Drought Conditions in a Rangeland Ecosystem, Vadose Zone Journal, 10.2136/vzj2016.04.0036, 15, 10, (1-12), (2016).
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  • Jiří Šimůnek, Martinus Th. Genuchten, Miroslav Šejna, Recent Developments and Applications of the HYDRUS Computer Software Packages, Vadose Zone Journal, 10.2136/vzj2016.04.0033, 15, 7, (1-25), (2016).
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