Physical property and gas transport studies of ultrathin polysulfone membrane from 298.15 to 328.15 K and 2 to 50 bar: atomistic molecular simulation and empirical modelling

Lock, S.S.M. and Lau, K.K. and Jusoh, N. and Shariff, A.M. and Yeong, Y.F. and Yiin, C.L. and Ammar Taqvi, S.A. (2020) Physical property and gas transport studies of ultrathin polysulfone membrane from 298.15 to 328.15 K and 2 to 50 bar: atomistic molecular simulation and empirical modelling. RSC Advances, 10 (54). pp. 32370-32392.

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Abstract

Elucidation of ultrathin polymeric membrane at the laboratory scale is complicated at different operating conditions due to limitation of instruments to obtainin situmeasurement data of membrane physical properties. This is essential since their effects are reversible. In addition, tedious experimental work is required to collect gas transport data at varying operating conditions. Recently, we have proposed a validated Soft Confining Methodology for Ultrathin Films that can be used to simulate ultrathin polysulfone (PSF) membranes upon confinement limited to 308.15 K and 2 bars. In industry application, these ultrathin membranes are operated within 298.15-328.15 K and up to 50 bars. Therefore, our proposed methodology using computational chemistry has been adapted to circumvent limitation in experimental study by simulating ultrathin PSF membranes upon confinement at different operating temperatures (298.15 to 328.15 K) and pressures (2 to 50 bar). The effect of operating parameters towards non-bonded and potential energy, free volume, specific volume and gas transport data (e.g.solubility and diffusivity) for oxygen and nitrogen of the ultrathin films has been simulated and collected using molecular simulation. Our previous empirical equations that have been confined to thickness dependent gas transport properties have been modified to accommodate the effect of operating parameters. The empirical equations are able to provide a good quantitative characterization withR2� 0.99 consistently, and are able to be interpolated to predict gas transport properties within the range of operating conditions. The modified empirical model can be utilized in process optimization studies to determine optimal membrane design for typical membrane specifications and operating parameters used in industrial applications. © The Royal Society of Chemistry 2020.

Item Type: Article
Impact Factor: cited By 1
Uncontrolled Keywords: Computational chemistry; Gases; Membranes; Molecular oxygen; Molecular structure; Optimization; Potential energy; Transport properties, Different operating conditions; Gas transport properties; Industry applications; Membrane physical properties; Molecular simulations; Polysulfone (PSF) membranes; Polysulfone membranes; Quantitative characterization, Ultrathin films
Depositing User: Ms Sharifah Fahimah Saiyed Yeop
Date Deposited: 25 Mar 2022 03:18
Last Modified: 25 Mar 2022 03:18
URI: http://scholars.utp.edu.my/id/eprint/30017

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