Abstract
The balances of mass, linear momentum and energy for a continuum provide jump relations between values of the physical variables on the two sides of a singular surface, either a boundary of the medium or an interior surface. In the case of a mixture, an overlap of interacting continua, there are jump relations for each constituent. While an elementary phase change front across which one phase of a constituent is transformed completely to a different phase can be treated as a single constituent, more general situations have co-existing phases on one side of the front, each with their own density, velocity, stress and internal energy fields, which must be treated as separate constituents. The phase change is now a mass transfer between constituents which becomes a surface production term in the mass balance jump relation for each constituent. In turn this implies surface production contributions to the momentum and energy relations associated with the surface mass transfer, including interaction body force and energy transfer contributions as well as the direct transfer terms. The general jump relations with such surface production contributions are formulated, and are illustrated for a number of situations arising in polythermal ice sheets and wet snow packs.
This is a preview of subscription content, log in via an institution to check access.
Similar content being viewed by others
References
Truesdell C (1965) On the foundations of mechanics and energetics. In: The Rational Mechanics of Materials. pp.293–304. New York Gordon and Breach
Morland L W (1992) Flow of viscous fluids through a porous deformable matrix. Surveys in Geophys. 13:209–268
Gurtin M E (1986) On the two phase Stefan problem with interface energy and entropy. Arch.Rat.Mech.Anal. 96:199–241
Gurtin M E (1988) Toward a non-equilibrium thermodynamics of two-phase materials. Arch.Rat.Mech.Anal. 100:275–312
Gurtin M E (1988) Multi-phase thermomechanics with interfacial structure-1. Heat conduction and the capillary balance law. Arch.Rat.Mech.Anal. 104:195–221
Gurtin M E (1993) The dynamics of solid-solid phase transitions-1. Coherent transitions. Arch.Rat.Mech.Anal. 123:305–335
Abeyaratne R, Knowles J K (1990) On the driving traction acting on a surface of strain discontinuity in a continuum. J.Mech.Phys.Solids 38:345–360
Alts T, Hutter K (1988) Continuum description of the dynamics and thermodynamics of phase boundaries between ice and water. Part I: Surface balance laws and their interpretation in terms of three-dimensional balance laws averaged over the phase change boundary layer. J.Non-Equil.Thermodyn. 13:221–257
Alts T, Hutter K (1988) Continuum description of the dynamics and thermodynamics of phase boundaries between ice and water. Part II: Thermodynamics. J.Non-Equil.Thermodyn. 13:259–280
Alts T, Hutter K (1988) Continuum description of the dynamics and thermodynamics of phase boundaries between ice and water. Part III: Thermostatics and its consequences. J.Non-Equil.Thermodyn. 13:301–329
Alts T, Hutter K (1989) Continuum description of the dynamics and thermodynamics of phase boundaries between ice and water. Part IV: On thermostatic stability and well posedness. J.Non-Equil.Thermodyn. 14:1–22
Kelly P D (1964) A reacting continuum. Int.J.Eng.Sci. 2:129–153
Hutter K (1983) Theoretical Glaciology. 510 pp, Dordrecht Reidel
Hutter K (1993) Thermo-mechanically coupled ice-sheet response -cold, polythermal, temperate. J.Glaciology 39:65–86
Gray J M N T Water movement in isothermal wet snow. Phil.Trans.Roy.Soc. (submitted)
Author information
Authors and Affiliations
Rights and permissions
About this article
Cite this article
Morland, L.W., Gray, J.M.N.T. Phase change interactions and singular fronts. Continuum Mech. Thermodyn 7, 387–414 (1995). https://doi.org/10.1007/BF01175665
Received:
Issue Date:
DOI: https://doi.org/10.1007/BF01175665