Explicit solutions for a two-phase unidimensional Lamé–Clapeyron–Stefan problem with source terms in both phases

A two-phase Stefan problem with heat source terms of a general similarity type in both liquid and solid phases for a semi-infinite phase-change material is studied. We assume the initial temperature is a negative constant and we consider two different boundary conditions at the fixed face x = 0 , a...

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Bibliographic Details
Published in:Journal of mathematical analysis and applications 2007-05, Vol.329 (1), p.145-162
Main Authors: Briozzo, A.C., Natale, M.F., Tarzia, D.A.
Format: Article
Language:English
Subjects:
Exact sciences and technology
Free boundary problem
Fusion
Heat source
Lamé–Clapeyron solution
Mathematical analysis
Mathematics
Neumann solution
Partial differential equations
Phase-change process
Sciences and techniques of general use
Similarity solution
Stefan problem
Sublimation–dehydration process
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Summary:A two-phase Stefan problem with heat source terms of a general similarity type in both liquid and solid phases for a semi-infinite phase-change material is studied. We assume the initial temperature is a negative constant and we consider two different boundary conditions at the fixed face x = 0 , a constant temperature or a heat flux of the form − q 0 / t ( q 0 > 0 ) . The internal heat source functions are given by g j ( x , t ) = ρ l t β j ( x 2 a j t ) ( j = 1 solid phase; j = 2 liquid phase) where β j = β j ( η ) are functions with appropriate regularity properties, ρ is the mass density, l is the fusion latent heat by unit of mass, a j 2 is the diffusion coefficient, x is the spatial variable and t is the temporal variable. We obtain for both problems explicit solutions with a restriction for data only for the second boundary conditions on x = 0 . Moreover, the equivalence of the two free boundary problems is also proved. We generalize the solution obtained in [J.L. Menaldi, D.A. Tarzia, Generalized Lamé–Clapeyron solution for a one-phase source Stefan problem, Comput. Appl. Math. 12 (2) (1993) 123–142] for the one-phase Stefan problem. Finally, a particular case where β j ( j = 1 , 2 ) are of exponential type given by β j ( x ) = exp ( − ( x + d j ) 2 ) with x and d j ∈ R is also studied in details for both boundary temperature conditions at x = 0 . This type of heat source terms is important through the use of microwave energy following [E.P. Scott, An analytical solution and sensitivity study of sublimation–dehydration within a porous medium with volumetric heating, J. Heat Transfer 116 (1994) 686–693]. We obtain a unique solution of the similarity type for any data when a temperature boundary condition at the fixed face x = 0 is considered; a similar result is obtained for a heat flux condition imposed on x = 0 if an inequality for parameter q 0 is satisfied.
ISSN:0022-247X
1096-0813
DOI:10.1016/j.jmaa.2006.05.083