TY - JOUR
T1 - Modeling Water Transport in Interlayered Thin-Film Nanocomposite Membranes
T2 - Gutter Effect vs Funnel Effect
AU - Wang, Fei
AU - Yang, Zhe
AU - Tang, Chuyang Y.
N1 - Funding Information:
This work was substantially supported by the Innovation and Technology Fund (Project # ITS/249/20) of the Hong Kong Special Administrative Region, China. We also acknowledge the partial support by a grant from the General Research Fund (Project # 17201921) of the Research Grants Council of Hong Kong.
Publisher Copyright:
© 2012 American Chemical Society. All rights reserved.
PY - 2022/11/11
Y1 - 2022/11/11
N2 - Interlayered thin-film nanocomposite (TFNi) membranes have experimentally demonstrated a great potential for achieving major gains in water permeance over conventional thin-film composite membranes, making them promising candidates for many environmental applications. Nevertheless, existing literature often reports contradicting observations on the effectiveness of interlayers. In this study, we implement a three-dimensional solution-diffusion model to analyze a geometry-induced funnel effect and an interlayer-promoted gutter effect. Our simulation results suggest that even an ultrathin interlayer of a few nanometers in thickness could serve as a low-resistance gutter layer, which minimizes the transversal water transport in the less permeable polyamide layer and thereby mitigate the unfavorable funnel effect. The actual available water permeance is bounded by the ideal polyamide-limited upper bound and the substrate-limited lower bound, with the interlayer regulating the competition between the funnel effect and the gutter effect. Water permeance can be potentially improved by an order of magnitude with the interlayer, and this enhancement is more pronounced for thinner polyamide layers, less porous substrates, and more permeable interlayers. We further analyze the role of the interlayer on improving the flux distribution/uniformity over a membrane surface, which has major implications on membrane fouling propensity. Our study establishes a theoretical framework for understanding the fundamental transport mechanisms in TFNi membranes, which provides important guidance on the future development of high-performance desalination membranes.
AB - Interlayered thin-film nanocomposite (TFNi) membranes have experimentally demonstrated a great potential for achieving major gains in water permeance over conventional thin-film composite membranes, making them promising candidates for many environmental applications. Nevertheless, existing literature often reports contradicting observations on the effectiveness of interlayers. In this study, we implement a three-dimensional solution-diffusion model to analyze a geometry-induced funnel effect and an interlayer-promoted gutter effect. Our simulation results suggest that even an ultrathin interlayer of a few nanometers in thickness could serve as a low-resistance gutter layer, which minimizes the transversal water transport in the less permeable polyamide layer and thereby mitigate the unfavorable funnel effect. The actual available water permeance is bounded by the ideal polyamide-limited upper bound and the substrate-limited lower bound, with the interlayer regulating the competition between the funnel effect and the gutter effect. Water permeance can be potentially improved by an order of magnitude with the interlayer, and this enhancement is more pronounced for thinner polyamide layers, less porous substrates, and more permeable interlayers. We further analyze the role of the interlayer on improving the flux distribution/uniformity over a membrane surface, which has major implications on membrane fouling propensity. Our study establishes a theoretical framework for understanding the fundamental transport mechanisms in TFNi membranes, which provides important guidance on the future development of high-performance desalination membranes.
KW - funnel effect
KW - gutter effect
KW - interlayered thin-film nanocomposite (TFNi)
KW - polyamide membranes
KW - water permeance enhancement
UR - http://www.scopus.com/inward/record.url?scp=85137852008&partnerID=8YFLogxK
U2 - 10.1021/acsestengg.2c00133
DO - 10.1021/acsestengg.2c00133
M3 - Journal article
AN - SCOPUS:85137852008
SN - 2690-0645
VL - 2
SP - 2023
EP - 2033
JO - ACS ES and T Engineering
JF - ACS ES and T Engineering
IS - 11
ER -