SEARCH

SEARCH BY CITATION

Literature Cited

  • 1
    Washburn EW. The dynamics of capillary flow. Phys Rev. 1921; 17: 273283.
  • 2
    Richards LA. Capillary conduction of liquids through porous mediums. Physics. 1931; 1: 318333.
  • 3
    Scheidegger AE. Physics of Flow Through Porous Media. Toronto: University of Toronto Press, 1974.
  • 4
    Ianson SJ, Hoff WD. Water movement in porous building materials. Effects of evaporative drying on height of capillary rise equilibrium in walls. Build Environ. 1986; 21: 195200.
  • 5
    Hall C, Hoff WD, Nixon MR. Water-movement in porous building materials. Evaporation and drying in brick and block materials. Build Environ. 1984; 19: 1320.
  • 6
    Liu JY. Drying of porous materials in a medium with variable potentials. J Heat Transfer Trans ASME. 1991; 113: 757762.
  • 7
    Alava M, Dube M, Rost M. Imbibition in disordered media. Adv Phys. 2004; 53: 83175.
  • 8
    Faybishenko B. Nonlinear dynamics in flow through unsaturated fractured porous media: status and perspectives. Rev Geophys. 2004; 42: 30.
  • 9
    Philip JR, de Vries DA. Moisture movement in porous media under temperature gradients. Trans Am Geophys Union. 1957; 38: 222232.
    Direct Link:
  • 10
    Nassar IN, Horton R. Water transport in unsaturated nonisothermal salty soil. I. Experimental results. Soil Sci Soc Am J. 1989; 27: 13231329.
  • 11
    Nassar IN, Horton R. Water transport in unsaturated nonisothermal salty soil. II. Theoretical development. Soil Sci Soc Am J. 1989; 27: 13301337.
  • 12
    Zhang FC, Zhang RD, Kang SZ. Estimating temperature effects on water flow in variably saturated soils using activation energy. Soil Sci Soc Am J. 2003; 67: 13271333.
  • 13
    Darcy H. Les Fontaines Publiques de la Ville de Dijon. Paris: Victor Dalmont, 1856.
  • 14
    Whitaker S. Flow in porous media II: governing equations for immiscible two-phase flow. Transp Porous Media. 1986; 1: 105.
  • 15
    Bear J, Verruijt A. Modelling Groundwater Flow and Pollution, Theory and Applications of Transport in Porous Media. Boston, MA: Reidel, 1972.
  • 16
    Helmig R. Multiphase Flow and Transport Processes in the Subsurface. Berlin: Springer, 1997: 367.
  • 17
    Hassanizadeh SM, Gray WG. Mechanics and thermodynamics of multiphase flow in porous media including interphase boundaries. Adv Water Resour. 1990; 13: 169186.
  • 18
    Hassanizadeh SM, Gray WG. Thermodynamic basic of capillary pressure in porous media. Water Resour Res. 1993; 29: 33893405.
  • 19
    Beliaev AY, Hassanizadeh SM. Theoretical model of hysterisis and dynamic effects in the capillary relation for two-phase flow in porous media. Transp Porous Media. 2001; 43: 487510.
  • 20
    Beliaev AY, Schotting RJ. Analysis of a new model for unsaturated flow in porous media including hysteresis and dynamic effects. Comput Geosci. 2001; 5: 345368.
  • 21
    Murdoch AI, Haassanizadeh SM. Macro-scale balance relations for bulk, interfacial and common line systems in multiphase flows. Int J Multiphase Flow. 2002; 28: 10911123.
  • 22
    Hassanizadeh SM, Celia MA, Dahle HK. Dynamic effect in the capillary pressure-saturation relationship and its impact on unsaturated flow. Agric Sci. 2002; 7: 6971.
  • 23
    Das DB, Gauldie R, Mirzaei M. Dynamic effects in capillary pressure relationships for two-phase flow in porous media: implications of fluid properties. AIChE J. 2007; 53: 25052520.
  • 24
    Das DB, Hassanizadeh SM. Upscaling Multiphase Flow in Porous Media: From Pore to Core and Beyond. Berlin: Springer, 2005: 13; ISBN: 1-4020-3513-6.
  • 25
    Das DB, Hassanizadeh SM, Rotter BE, Ataie-Ashtiani B. A numerical study of micro-heterogeneity effects on upscaled properties of twophase flow in porous media. Transp Porous Media. 2004; 56: 329350.
  • 26
    Mirzaei M, Das DB. Dynamic effects in capillary pressure saturations relationships for two-phase flow in 3D porous media: implications of micro-heterogeneities. Chem Eng Sci. 2007; 62: 19271947.
  • 27
    Sinnokrot AA, Ramey HJ Jr, Marsden SS Jr. Effect of temperature level upon capillary pressure curves. Soc Petrol Eng (SPE) J. 1971; 11: 1322.
  • 28
    Nutt CW. The physical basis of the displacement of oil from porous media by other fluids: a capillary bundle model. Proc R Soc London Ser A Math Phys Sci. 1981; 382: 55178.
  • 29
    Davis EL. Effect of temperature and pore size on the hydraulic properties and flow of a hydrocarbon oil in the subsurface. J Contam Hydrol. 1994; 16: 5586.
  • 30
    Imhoff PT, Frizzell A, Miller CT. Evaluation of thermal effect on the dissolution of nonaqueous phase liquid in porous media. Environ Sci Technol. 1997; 31: 16151622.
  • 31
    Grant SA, Salehzadeh A. Calculation of temperature effects on wetting coefficients of porous solids and their capillary pressure functions. Water Resour Res. 1996; 32: 261270.
  • 32
    Gatmiri B, Delage P. A formulation of fully coupled thermal hydraulic-mechanical behaviour of saturated porous media—numerical approach. Int J Numer Anal Methods Geomech. 1997; 21: 199225.
  • 33
    She HY, Sleep BE. The effect of temperature on capillary pressure saturation relationships for air-water and perchloroethylene-water systems. Water Resour Res. 1998; 34: 25872597.
  • 34
    Narasimhan A, Lage JL. Modified Hazen-Dupuit-Darcy model for forced convection of a fluid with temperature-dependent viscosity. J Heat Transfer. 2001; 123: 3139.
  • 35
    Muralidhar K, Sheorey T. Isothermal and non-isothermal oil-water flow and viscous fingering in porous media. Int J Therm Sci. 2003; 42: 665676.
  • 36
    Grant SA. Extension of a temperature effects model for capillary pressure-saturation relations. Water Resour Res. 2003; 39: 1003.
  • 37
    Hanyga A, Jianfei L. Thermal effects in immiscible two-fluid porous flow. Int J Eng Sci. 2004; 42: 291301.
  • 38
    Schembre JM, Kovscek AR. Mechanism of formation damage at elevated temperature. J Energy Resour. 2005; 127: 171180.
  • 39
    Schembre JM, Kovscek AR. Estimation of dynamic relative permeability and capillary pressure from countercurrent imbibition experiments. Transp Porous Media. 2006; 65: 3151.
  • 40
    Schembre JM, Tang G-Q, Kovscek AR. Inter-relationship of temperature, wettability on relative permeability of heavy oil in diatomaceous rocks. Soc Petrol Eng. 2006; 9: 239250.
  • 41
    Lo H, Mungan N. Effect of temperature on water-oil relative permeabilities in oil-wet and water-wet systems, In: Society of Petroleum Engineers of AIME Meeting, 1973; Las Vegas, NV.
  • 42
    Haar L, Gallager JS, Kell GSA. NBS/NRC Steam Tables. New York: McGraw Hill, 1984.
  • 43
    Parker JC, Lenhard RJ. A model for hysteretic constitutive relations governing multiphase flow. I. Saturation-pressure relations. Water Resour Res. 1987; 23: 21872196.
  • 44
    Van Genuchten MT. Closed-form equation for predicting the hydraulic conductivity of unsaturated soils. Soil Sci Soc Am J. 1980; 44: 892898.
  • 45
    Muskat M, Meres M. Flow of heterogeneous fluids in porous media. Physics. 1936; 7: 346363.
  • 46
    Demond AH, Roberts PV. Relative permeability for two-phase flow in porous media. Am Water Resour Bull. 1987; 23: 617628.
  • 47
    Marshall TJ, Holmes JW. Soil Physics. New York: Cambridge University Press, 1979.
  • 48
    Farouki TO. Thermal Properties of Soil. Germany: Trans Tech Publications, 1986: 2930.
  • 49
    Mandal JN, Divshikar DG. Soil Testing in Civil Engineering. Brookfield, USA: Balkema Press, 1995: 1090.
  • 50
    Kozak JA, Ahuja LR. Scaling of infiltration and redistribution of water across soil texture. Soil Sci Soc. 2005; 69: 816827.
  • 51
    Brooks RH, Corey AT. Hydraulic Properties of Porous Media. Hydrology Papers. Fort Collins, CO: Colorado State University, 1964.
  • 52
    Grant SA, Bachmann J. Effect of temperature on capillary pressure. In: Environmental Mechanics, Water, Mass & Energy Transform in Biosphere: American Geophysical Society; Geophyscal Monograph server. American Geophysical Society, 2002, 129: 199212 Washington DC.
  • 53
    Yaws CL. Chemical Properties Handbook. Toronto: McGraw-Hill, 1999: 779.
  • 54
    Oostrom M, Meck DH, White MD. STOMP an Introductory Short Course. Richland, WA: Pacific Northwest National Laboratory, 2003.
  • 55
    Meyer CA, Mclintock RB, Silvestri GJ, Spencer RC. ASME Steam Tables: Thermodynamic and Transport for Steam and Water. 6th Ed. 1967: 1330, American Society of Mechanical Engineers, New York.
  • 56
    White MD, Oostrom M. Technical Report, Pacific Northwest National Laboratory, Richland, WA, 2000, STOMP subsurface transport over multiple phases Version 2.0 User's Guide PNNL 12034.
  • 57
    White MD, Oostrom M. STOMP 2.0 Theory Guide. Richland, WA: Pacific Northwest National Laboratory, PNNL-12030, UC-2010, 2000.
  • 58
    Reid RC, Prausnitz JM, Poling BE. Properties of Gas and Liquids. New York: McGraw Hill, 1987: 433485.
  • 59
    White MD, Oostrom M. STOMP 4.0 User Guide. Richland, WA: Pacific Northwest National Laboratory, PNNL-17782, 2006.
  • 60
    Nichols WE, Aimo NJ, Oostrom M, White MD. STOMP Application Guide. Richland, WA: Pacific Northwest National Laboratory, PNNL-11216, UC-2010, 1997.
  • 61
    Schroth MH, Istok JD, Selker JS, Oostrom M, White MD. Multifluid flow in bedded porous media: laboratory experiments and numerical simulations. Adv Water Res. 1998; 22: 169183.
  • 62
    Ataie-Ashtiani B, Hassanizadeh SM, Oostrom M, Celia MA, White MD. Effective parameters for two-phase flow in a porous medium with periodic heterogeneities. J Contam Hydrol. 2001; 49: 87109.
  • 63
    Ataie-Ashtiani B, Hassanizadeh SM, Celia MA. Effects of heterogeneities on capillary pressure-saturation relative permeability relationships. J Contam Hydrol. 2002; 56: 175192.
  • 64
    Ataie-Ashtiani B, Hassanizadeh SM, Oung O, Westrate FA, Bezuijen A. Numerical modeling of two-phase flow in geocentrifuge. Environ Model Software. 2003; 18: 231241.
  • 65
    Das DB, Mirzaei M, Widdows N. Non-uniqueness in capillary pressure-saturation-relative permeability relationship for two phase porous flow. Chem Eng Sci. 2006; 61: 67866803.
  • 66
    Osoba JS, Richardson JJ, Kerver JK, Hafford JA, Blair PM. Laboratory measurements of capillary pressure and relative permeability. Trans AIME. 1951; 192: 4755.
  • 67
    Johnson EF, Bossier DP, Naumann VO. Calculation of relative permeability from displacement experiments. Trans AIME. 1959; 370: 216.
  • 68
    Haines WB. Studies in the physical properties of soil hysteresis effect in capillary properties and modes of moisture distribution associated therewith. J Agric Sci. 1930; 20: 97116.
  • 69
    Stauffer F. Time dependence of the relationship between capillary pressure, water content and conductivity during drainage of porous media. In: Proceedings of the IAHR Conference on Scale Effects in Porous Media, Thessaloniki, Greece, 1979.
  • 70
    Manthey S, Hassanizadeh SM. Macro-scale dynamic effects in homogeneous and heterogeneous porous media. Transp Porous Media. 2005; 58: 121145.
  • 71
    O'Carroll DM, Phelan TJ, Abriola LM. Exploring dynamic effects in capillary pressure in multistep outflow experiments. Water Resour Res. 2005; 41: W11419.