Sensitivity of a Continuum‐Scale Porous Media Heat and Mass Transfer Model to the Spatial‐Discretization Length‐Scale of Applied Atmospheric Forcing Data

Fundamental process understanding and description of heat, mass, and momentum exchanges across the land‐atmosphere interface in model boundary forcing parameterizations is critical to the simulation of near‐surface soil moisture dynamics (e.g., bare‐soil evaporation). This study explores the sensiti...

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Bibliographic Details
Published in:Water resources research 2019-04, Vol.55 (4), p.3520-3540
Main Authors: Trautz, Andrew C., Illangasekare, Tissa H., Howington, Stacy, Cihan, Abdullah
Format: Article
Language:English
Subjects:
Atmospheric data
Atmospheric forcing
bare‐soil evaporation
Computer simulation
continuum‐scale model sensitivity
Data
Data collection
Discretization
Dynamics
Evaporation
Heat and mass transfer
Heat exchange
Heat transfer
Length
Mass
Mass transfer
model data requirements
Momentum
Porous media
Resolution
Sensitivity
Simulation
Soil
Soil conditions
Soil dynamics
Soil moisture
Soil properties
Soil surfaces
Spatial discrimination
Spatial distribution
Spatial resolution
spatial‐discretization of atmospheric forcing data sets
State variable
Water loss
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Summary:Fundamental process understanding and description of heat, mass, and momentum exchanges across the land‐atmosphere interface in model boundary forcing parameterizations is critical to the simulation of near‐surface soil moisture dynamics (e.g., bare‐soil evaporation). This study explores the sensitivity of a continuum‐scale porous media heat and mass transfer model to the spatial‐discretization length‐scales (i.e., spatial‐resolution) of near‐surface atmospheric data; the goal is to determine how much data are needed to force the model and adequately capture evaporative water losses and subsurface state variable distributions. The requisite atmospheric forcing data were taken from the high‐resolution, precision bare‐soil evaporation experiments of Trautz et al. (2018, https://doi.org/10.1029/2018WR023102). Simulation results demonstrated that shallow subsurface mass and heat transfer dynamics can be adequately captured with forcing data averaged over large length‐scales, or a minimal number of measurements, provided that soil conditions are properly described. The soil moisture spatial distributions were found to be insensitive to horizontal variations in the forcing data. The model failed to capture small‐scale trends observed experimentally; this did not impact the accuracy of total evaporative water loss estimates however. These results indicate that in future physical experimental efforts conducted at 1–10‐m length‐scales, there is no need to focus on the generation of high‐spatial resolution atmospheric measurements—time and effort would be better spent in characterizing soil conditions and properties. Even though a theoretical foundation was not provided to directly extrapolate this work to the field scale, these findings have practical value in designing field data collection strategies. Key Points System surface condition‐dependent coupling strength should be considered when conducting atmospheric sampling and soil characterization High spatial resolution forcing data are not needed for reproducing evaporation dynamics at the continuum scale for simple soil surface conditions
ISSN:0043-1397
1944-7973
DOI:10.1029/2018WR023923