A non-equilibrium model for soil heating and moisture transport during  extreme surface heating: the soil (heat–moisture–vapor) HMV-Model Version 1

Massman, W. J.

doi:10.5194/gmd-8-3659-2015

Cited by 19 publications

(41 citation statements)

References 65 publications

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“…This is because of the strong, near exponential variation of

ρ_{v}^{*} false(T false)

which plays a particularly important role for the Quincy sand case under surface fire conditions. This calls into question the results of Massman () who claimed that the nonequilibrium evaporation source term he used in his model, one version of which was based on Novak (), was critical to the improved performance of his simulations compared with Massman () and the original theory in Campbell et al (). The results herein suggest that the more likely source of the improvement was the inclusion of liquid flow which was neglected in both Campbell et al () and Massman ().…”

Section: Application Of the Improved Novak (2012) Model For Sementioning

confidence: 99%

“…Yamanaka et al () used a different sand but the same loam and clay soils in their numerical evaporation simulations based on PdV57. The Quincy sand was one of the soils used in the Campbell et al () surface fire experiments and numerical calculations and the Massman (, ) surface fire numerical simulations. The dependence of h v on T shown in the figure is solely due to the dependence of D v on T , which was given by D v ( T )=2.12×10 −5 ( T /273.15) 2 m 2 s −1 (Campbell, ).…”

Section: Application Of the Improved Novak (2012) Model For Sementioning

confidence: 99%

See 1 more Smart Citation

Validity of Assuming Equilibrium Between Liquid Water and Vapor for Simulating Evaporation

Novak

2019

Water Resources Research

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The standard assumption used in evaporation theory that at any location in a soil water vapor density is equal to the value in thermodynamic equilibrium with the liquid water has recently been questioned. This paper defines precise criteria for nonequilibrium to occur during evaporation in soils. In doing so a physically based model of the pore transfer coefficient critical to quantifying the degree of nonequilibrium is developed. The likelihood of departure from the equilibrium assumption for various soil textures and temperature conditions, including the extreme case of surface fire, is presented. Furthermore the pore transfer coefficient is incorporated into steady‐state nonequilibrium simulations of evaporation from a coarse sand under field conditions and compared with the corresponding equilibrium simulation. Outside of the narrow subsurface evaporation zone there were no significant differences between the nonequilibrium and equilibrium simulations. Since nonequilibrium effects were most likely to be seen with the coarse sand abandoning the standard assumption in future work is unnecessary, and all previous work based on it need not be questioned.

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“…This is because of the strong, near exponential variation of

ρ_{v}^{*} false(T false)

Section: Application Of the Improved Novak (2012) Model For Sementioning

confidence: 99%

Section: Application Of the Improved Novak (2012) Model For Sementioning

confidence: 99%

Validity of Assuming Equilibrium Between Liquid Water and Vapor for Simulating Evaporation

Novak

2019

Water Resources Research

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“…The f = 1 correction factor in Equation 8 accounts for the nonuniformity of the porous media, that is, represents smooth uniform spherical grains. Smits et al (2012) and Massman (2015) considered the film flow according to Equation 8 in their models and acknowledged the importance of considering the hydraulic conductivity due to the film flow for dry state conditions. But they found no improvement in the numerical results.…”

Section: Soil-water Retention Characteristicsmentioning

confidence: 99%

“…In addition, the experimental observation showed that the liquid‐gas interfacial area reaches its maximum value at a low saturation degree for sands (Costanza‐Robinson & Brusseau, 2002). Since there is limited research on predicting the interfacial area, a parabolic function proposed by Costanza‐Robinson and Brusseau (2002) and Massman (2015) is used in this study with a slight modification:

a_{\lg} = α_{1} S_{l} {(1 - S_{l})}^{α_{2}} + α_{3} {[S_{l} (1 - S_{l})]}^{α_{4}} .

α 1 = 50, α 2 = 20, α 3 = 0.22, and α 4 = 0.25 are fitting parameters. Considering Equation and the fitting parameters, the interfacial area reaches its maximum value at S l = 1%.…”

Section: Theoretical Formulation Of Nonisothermal Multiphase Flowmentioning

confidence: 99%

“…Nuske et al (2014) extended the model proposed by Class et al (2002) to include the effects of thermal and chemical nonequilibrium phenomena, where they concluded that considering chemical nonequilibrium (which may lead to NEPC) is of higher importance than the thermal nonequilibrium. Moreover, Massman (2015) studied the coupled mass and heat flow during wildfires considering a NEPC model. He proposed that the chemical potential of water cannot be in equilibrium with water vapor for soils closed to dry condition when almost no liquid water exists.…”

Section: Introductionmentioning

confidence: 99%

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Utilization of Nonequilibrium Phase Change Approach to Analyze the Nonisothermal Multiphase Flow in Shallow Subsurface Soils

Tamizdoust

Ghasemi‐Fare

2020

Water Resources Research

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The prediction of coupled nonisothermal multiphase flow in porous media has been the subject of many theoretical and experimental studies in the past half a century. In particular, the evaporation phenomenon from the shallow subsurface has been extensively studied based on the notion of equilibrium phase change between liquid water and water vapor (i.e., instantaneous phase change). One of the frequent assumptions in equilibrium phase change approach is that liquid water is hydraulically connected throughout the vadose zone. Furthermore, classical soil-water retention curves (e.g., van Genuchten model), which have been extensively used in the literature to model evaporation process, are only valid for high and intermediate saturation degrees. Although these limitations have been addressed and improved in separate studies, they have not yet been rigorously incorporated in the numerical modeling of nonisothermal multiphase flow in shallow subsurface of in-field soils. Therefore, the aim of this study is to investigate the coupled heat, liquid, and vapor flow in soil media through the Hertz-Knudsen-Schrage (HKS) phase change model and by incorporating a water retention model which captures the soil-water characteristics from full to oven-dried saturation degrees. A numerical model is developed and validated against the in-field experimental data. Reasonable agreements between the calculated and measured values of water contents at all depths, as well as the temperature, and cumulative evaporation are observed. Results also confirm that the contribution of the film flow in overall mass flow in the medium is required for accurate modeling and cannot be ignored.

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Soil Heating in Fire (SheFire): A model and measurement method for estimating soil heating and effects during wildland fires

Brady

Dickinson

Miesel

et al. 2022

Ecological Applications

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Fire has transformative effects on soil biological, chemical, and physical properties in terrestrial ecosystems around the world. While methods for estimating fire characteristics and associated effects aboveground have progressed in recent decades, there remain major challenges in characterizing soil heating and associated effects belowground. Overcoming these challenges is crucial for understanding how fire influences soil carbon storage, biogeochemical cycling, and ecosystem recovery. In this paper, we present a novel framework for characterizing belowground heating and effects. The framework includes (1) an open‐source model to estimate fire‐driven soil heating, cooling, and the biotic effects of heating across depths and over time (Soil Heating in Fire model; SheFire) and (2) a simple field method for recording soil temperatures at multiple depths using self‐contained temperature sensor and data loggers (i.e., iButtons), installed along a wooden stake inserted into the soil (i.e., an iStake). The iStake overcomes many logistical challenges associated with obtaining temperature profiles using thermocouples. Heating measurements provide inputs to the SheFire model, and modeled soil heating can then be used to derive ecosystem response functions, such as heating effects on microorganisms and tissues. To validate SheFire estimates, we conducted a burn table experiment using iStakes to record temperatures that were in turn used to fit the SheFire model. We then compared SheFire predicted temperatures against measured temperatures at other soil depths. To benchmark iStake measurements against those recorded by thermocouples, we co‐located both types of sensors in the burn table experiment. We found that SheFire demonstrated skill in interpolating and extrapolating soil temperatures, with the largest errors occurring at the shallowest depths. We also found that iButton sensors are comparable to thermocouples for recording soil temperatures during fires. Finally, we present a case study using iStakes and SheFire to estimate in situ soil heating during a prescribed fire and demonstrate how observed heating regimes would influence seed and tree root vascular cambium survival at different soil depths. This measurement‐modeling framework provides a cutting‐edge approach for describing soil temperature regimes (i.e., soil heating) through a soil profile and predicting biological responses.

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A non-equilibrium model for soil heating and moisture transport during extreme surface heating: the soil (heat–moisture–vapor) HMV-Model Version 1

Cited by 19 publications

References 65 publications

Validity of Assuming Equilibrium Between Liquid Water and Vapor for Simulating Evaporation

Validity of Assuming Equilibrium Between Liquid Water and Vapor for Simulating Evaporation

Utilization of Nonequilibrium Phase Change Approach to Analyze the Nonisothermal Multiphase Flow in Shallow Subsurface Soils

Soil Heating in Fire (SheFire): A model and measurement method for estimating soil heating and effects during wildland fires

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