A model for wet-casting polymeric membranes incorporating nonequilibrium interfacial dynamics, vitrification and convection
A new model is developed for wet-casting polymeric membranes that address how the concentrations at the interface between the casting solution and nonsolvent bath adjust from initial nonequilibrium to equilibrium values on the binodal. Properly describing the evolution of the interface concentrati...
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sg-ntu-dr.10356-1003662020-03-07T12:48:43Z A model for wet-casting polymeric membranes incorporating nonequilibrium interfacial dynamics, vitrification and convection Lee, Hanyong. Krantz, William B. Hwang, Sun-Tak. Nanyang Environment and Water Research Institute Singapore Membrane Technology Centre DRNTU::Engineering::Civil engineering::Water resources A new model is developed for wet-casting polymeric membranes that address how the concentrations at the interface between the casting solution and nonsolvent bath adjust from initial nonequilibrium to equilibrium values on the binodal. Properly describing the evolution of the interface concentrations enables this new model to predict vitrification, which has been observed experimentally but not predicted heretofore. This new model also incorporates densification-induced convection that arises owing to density changes associated with the concentration gradients and contributes to the mass-transfer fluxes. The predictions for the cellulose acetate, acetone, and water system indicate that densificationinduced convection can increase the mass-transfer flux by nearly two orders-of-magnitude shortly after initiating wet-casting. This increased mass-transfer flux can have a marked effect on the properties of the functional layer of asymmetric membranes that is formed early in the casting process. The predictions for initial casting-solution thicknesses of 75 and 125 m are markedly different. When densification induced convection is included, the 125 m film is predicted to enter well into the metastable region, thereby allowing supersaturation that promotes macrovoid defects. Hence, this new model provides an explanation for the effect of casting-solution thickness on the occurrence of macrovoids. 2013-07-08T05:55:08Z 2019-12-06T20:21:14Z 2013-07-08T05:55:08Z 2019-12-06T20:21:14Z 2010 2010 Journal Article Lee, H., Krantz, W. B., & Hwang, S. T. (2010). A model for wet-casting polymeric membranes incorporating nonequilibrium interfacial dynamics, vitrification and convection. Journal of Membrane Science, 354(1-2), 74-85. 0376-7388 https://hdl.handle.net/10356/100366 http://hdl.handle.net/10220/11013 10.1016/j.memsci.2010.02.066 en Journal of membrane science © 2010 Elsevier B.V. |
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DRNTU::Engineering::Civil engineering::Water resources Lee, Hanyong. Krantz, William B. Hwang, Sun-Tak. A model for wet-casting polymeric membranes incorporating nonequilibrium interfacial dynamics, vitrification and convection |
| description |
A new model is developed for wet-casting polymeric membranes that address how the concentrations
at the interface between the casting solution and nonsolvent bath adjust from initial nonequilibrium
to equilibrium values on the binodal. Properly describing the evolution of the interface concentrations
enables this new model to predict vitrification, which has been observed experimentally but not predicted
heretofore. This new model also incorporates densification-induced convection that arises owing
to density changes associated with the concentration gradients and contributes to the mass-transfer
fluxes. The predictions for the cellulose acetate, acetone, and water system indicate that densificationinduced
convection can increase the mass-transfer flux by nearly two orders-of-magnitude shortly after
initiating wet-casting. This increased mass-transfer flux can have a marked effect on the properties of the
functional layer of asymmetric membranes that is formed early in the casting process. The predictions
for initial casting-solution thicknesses of 75 and 125 m are markedly different. When densification induced convection is included, the 125 m film is predicted to enter well into the metastable region,
thereby allowing supersaturation that promotes macrovoid defects. Hence, this new model provides an explanation for the effect of casting-solution thickness on the occurrence of macrovoids. |
| author2 |
Nanyang Environment and Water Research Institute |
| author_facet |
Nanyang Environment and Water Research Institute Lee, Hanyong. Krantz, William B. Hwang, Sun-Tak. |
| format |
Article |
| author |
Lee, Hanyong. Krantz, William B. Hwang, Sun-Tak. |
| author_sort |
Lee, Hanyong. |
| title |
A model for wet-casting polymeric membranes incorporating nonequilibrium interfacial dynamics, vitrification and convection |
| title_short |
A model for wet-casting polymeric membranes incorporating nonequilibrium interfacial dynamics, vitrification and convection |
| title_full |
A model for wet-casting polymeric membranes incorporating nonequilibrium interfacial dynamics, vitrification and convection |
| title_fullStr |
A model for wet-casting polymeric membranes incorporating nonequilibrium interfacial dynamics, vitrification and convection |
| title_full_unstemmed |
A model for wet-casting polymeric membranes incorporating nonequilibrium interfacial dynamics, vitrification and convection |
| title_sort |
model for wet-casting polymeric membranes incorporating nonequilibrium interfacial dynamics, vitrification and convection |
| publishDate |
2013 |
| url |
https://hdl.handle.net/10356/100366 http://hdl.handle.net/10220/11013 |
| _version_ |
1681049023024201728 |