An Improved Phenomenological Model for Polymer Desorption
We propose a phenomenological model for the
process of polymer desorption. In so doing, we omit the usual
theoretical approach of incorporating a fictitious viscoelastic
stress term into the flux equation. As a result, we obtain a
model that captures the essence of the phenomenon of trapping
skinning, while preserving the integrity of the experimentally
verified Fickian law for diffusion. An appropriate asymptotic
analysis is carried out, and a parameter is introduced to represent
the speed of the desorption front. Numerical simulations are
performed to illustrate the desorption dynamics of the model.
Recommendations are made for future modifications of the
model, and provisions are made for the inclusion of experimentally
determined frontal speeds.
[1] M. A. Samus and G. Rossi. Methanol absorption in ethylene-vinyl
achohol copolymers: Relation between solvent diffusion and changes
in glass transition temperature in glassy polymeric materials. Macromolecules,
29(6):2275-2288, 1996.
[2] G. Astarita and S. Joshi. Simple dimension effect in the sorption of
solvents in polymer - a mathematical model. J. Membr. Sci., 4:165-
182, 1978.
[3] G. Astarita and G. C. Sarti. A class of mathematical models for the
sorption of swelling solvent in glassy polymers. Polym. Eng. Sci.,
18:388-397, 1978.
[4] A. Friedman and G. Rossi. Phenomenological continuum equations
to describe case ii diffusion in polymeric materials. Macromolecules,
30:153-154, 1997.
[5] A. Peterlin. Diffusion in a network with discontinuous swelling. J. Poly.
Sci. B: Polym. Lett., 3:1083-1092, 1965.
[6] T. Qian and P. L. Taylor. From the thomas windle model to a
phenomenological description of case ii diffusion in polymers. Polymer,
52(19):7159-7163, 2000.
[7] G. Rossi, P. A. Pincus, and P. G. De Gennes. A phenomenological
description of case ii diffusion in polymeric materials. Europhys. Lett.,
32:391-396, 1995.
[8] N. L. Thomas and A. H. Windle. Transport of methanol in poly(methylmethocrylate).
Polymer, 19:255-265, 1978.
[9] N. L. Thomas and A. H. Windle. A deformation model for case ii
diffusion. Polymer, 21:613-619, 1980.
[10] N. L. Thomas and A. H. Windle. Diffusion mechanics of the system
pmma-methanol. Polymer, 22:627-639, 1981.
[11] N. L. Thomas and A. H. Windle. A theory of case ii diffusion. Polymer,
23:529-542, 1982.
[12] R. W. Cox and D. S. Cohen. A mathematical model for stress driven
diffusion in polymers. J. Poly. Sci. B: Poly. Phys., 27(3):589-602, 1989.
[13] D. A. Edwards. A spatially nonlocal model for polymer-penetrant
diffusion. J. Appl. Math. Phys., 52:254-288, 2001.
[14] D. A. Edwards. A mathematical mode for trapping skinning in polymers.
Stud. Appl. Math., 99:49-80, 1997.
[15] D. A. Edwards and R. A. Cairncross. Desorption overshoot in polymerpenetrant
systems: Asymptotic and computational results. SIAM J. Appl.
Math., 63:98-115, 2002.
[16] M. Sanapoulou, D. F. Stamatialis, and J. H. Petropoulos. Investigation of
case ii behavior. 1. theoretical studies based on the relaxation dependent
solubility model. Macromolecules, 35(3):1012-1020, 2002.
[17] D. M. G. Comissiong, J. A. Ferreira, and P. de Oliveira. A phenomenological
model for desorption in polymers. University of Coimbra,CMUC
Technical Report 06-35, 2006.
[18] M. Sanopoulou and J. H. Petropoulos. Systematic analysis and model interpretation
of micromolecular non-fickian sorption kinetics in polymer
films. Macromolecules, 34:1400-1410, 2001.
[19] C.Y. Hui, R. C. Wu, R. C. Lasky, and E. J. Kramer. Case ii diffusion in
polymers. ii. steady state front motion. J. Appl. Phys., 61:5137-5149,
1987.
[20] D. A. Edwards. Skinning during desorption of polymers: An asymptotic
analysis. SIAM J. Appl. Math., 59:1134-1155, 1999.
[21] J. Crank. The Mathematics of Diffusion. Oxford University Press,
Oxford, U.K., 1973.
[22] J. Crank. A theoretical investigation of the influence of molecular
relaxation and internal stress. J. Poly. Sci., 11:151-168, 1953.
[23] E. Bagley and F. A. Long. 2-stage sorption and desorption of organic
vapours in cellulose acetate. J. Am. Chem. Soc., 77:2172-2178, 1955.
[24] D. A. Edwards. An asymptotic analysis of polymer desorption and
skinning. Macromolecular Theory and Simulations, 8:10-14, 1999.
[25] G. Powers and J. Collier. Experimental modeling of solvent-casting thin
polymer films. J. Poly. Eng. Sci., 30:118-123, 1990.
[1] M. A. Samus and G. Rossi. Methanol absorption in ethylene-vinyl
achohol copolymers: Relation between solvent diffusion and changes
in glass transition temperature in glassy polymeric materials. Macromolecules,
29(6):2275-2288, 1996.
[2] G. Astarita and S. Joshi. Simple dimension effect in the sorption of
solvents in polymer - a mathematical model. J. Membr. Sci., 4:165-
182, 1978.
[3] G. Astarita and G. C. Sarti. A class of mathematical models for the
sorption of swelling solvent in glassy polymers. Polym. Eng. Sci.,
18:388-397, 1978.
[4] A. Friedman and G. Rossi. Phenomenological continuum equations
to describe case ii diffusion in polymeric materials. Macromolecules,
30:153-154, 1997.
[5] A. Peterlin. Diffusion in a network with discontinuous swelling. J. Poly.
Sci. B: Polym. Lett., 3:1083-1092, 1965.
[6] T. Qian and P. L. Taylor. From the thomas windle model to a
phenomenological description of case ii diffusion in polymers. Polymer,
52(19):7159-7163, 2000.
[7] G. Rossi, P. A. Pincus, and P. G. De Gennes. A phenomenological
description of case ii diffusion in polymeric materials. Europhys. Lett.,
32:391-396, 1995.
[8] N. L. Thomas and A. H. Windle. Transport of methanol in poly(methylmethocrylate).
Polymer, 19:255-265, 1978.
[9] N. L. Thomas and A. H. Windle. A deformation model for case ii
diffusion. Polymer, 21:613-619, 1980.
[10] N. L. Thomas and A. H. Windle. Diffusion mechanics of the system
pmma-methanol. Polymer, 22:627-639, 1981.
[11] N. L. Thomas and A. H. Windle. A theory of case ii diffusion. Polymer,
23:529-542, 1982.
[12] R. W. Cox and D. S. Cohen. A mathematical model for stress driven
diffusion in polymers. J. Poly. Sci. B: Poly. Phys., 27(3):589-602, 1989.
[13] D. A. Edwards. A spatially nonlocal model for polymer-penetrant
diffusion. J. Appl. Math. Phys., 52:254-288, 2001.
[14] D. A. Edwards. A mathematical mode for trapping skinning in polymers.
Stud. Appl. Math., 99:49-80, 1997.
[15] D. A. Edwards and R. A. Cairncross. Desorption overshoot in polymerpenetrant
systems: Asymptotic and computational results. SIAM J. Appl.
Math., 63:98-115, 2002.
[16] M. Sanapoulou, D. F. Stamatialis, and J. H. Petropoulos. Investigation of
case ii behavior. 1. theoretical studies based on the relaxation dependent
solubility model. Macromolecules, 35(3):1012-1020, 2002.
[17] D. M. G. Comissiong, J. A. Ferreira, and P. de Oliveira. A phenomenological
model for desorption in polymers. University of Coimbra,CMUC
Technical Report 06-35, 2006.
[18] M. Sanopoulou and J. H. Petropoulos. Systematic analysis and model interpretation
of micromolecular non-fickian sorption kinetics in polymer
films. Macromolecules, 34:1400-1410, 2001.
[19] C.Y. Hui, R. C. Wu, R. C. Lasky, and E. J. Kramer. Case ii diffusion in
polymers. ii. steady state front motion. J. Appl. Phys., 61:5137-5149,
1987.
[20] D. A. Edwards. Skinning during desorption of polymers: An asymptotic
analysis. SIAM J. Appl. Math., 59:1134-1155, 1999.
[21] J. Crank. The Mathematics of Diffusion. Oxford University Press,
Oxford, U.K., 1973.
[22] J. Crank. A theoretical investigation of the influence of molecular
relaxation and internal stress. J. Poly. Sci., 11:151-168, 1953.
[23] E. Bagley and F. A. Long. 2-stage sorption and desorption of organic
vapours in cellulose acetate. J. Am. Chem. Soc., 77:2172-2178, 1955.
[24] D. A. Edwards. An asymptotic analysis of polymer desorption and
skinning. Macromolecular Theory and Simulations, 8:10-14, 1999.
[25] G. Powers and J. Collier. Experimental modeling of solvent-casting thin
polymer films. J. Poly. Eng. Sci., 30:118-123, 1990.
@article{"International Journal of Engineering, Mathematical and Physical Sciences:64880", author = "Joanna Sooknanan and Donna Comissiong", title = "An Improved Phenomenological Model for Polymer Desorption", abstract = "We propose a phenomenological model for the
process of polymer desorption. In so doing, we omit the usual
theoretical approach of incorporating a fictitious viscoelastic
stress term into the flux equation. As a result, we obtain a
model that captures the essence of the phenomenon of trapping
skinning, while preserving the integrity of the experimentally
verified Fickian law for diffusion. An appropriate asymptotic
analysis is carried out, and a parameter is introduced to represent
the speed of the desorption front. Numerical simulations are
performed to illustrate the desorption dynamics of the model.
Recommendations are made for future modifications of the
model, and provisions are made for the inclusion of experimentally
determined frontal speeds.", keywords = "Phenomenological Model, Polymer, Desorption,
Trapping Skinning", volume = "3", number = "3", pages = "221-12", }
