Atomistic-Scale Energetic Heterogeneity on a Membrane Surface

• Published in: Membranes (Basel) Vol. 12; no. 10; p. 977
• Main Authors: Tan, Shiliang (Johnathan), Ong, Chisiang, Chew, Jiawei
• Format: Journal Article
• Language: English
• Published: Basel MDPI AG 01.10.2022; MDPI
• Subjects: Argon; Carbon dioxide; Composition; Dipole moments; Electrostatic properties; Electrostatics; energetic topology; Energy; Fluorides; Fluorine; Fluorine compounds; Fouling; Heterogeneity; Hydrophilicity; Hydrophobicity; interaction energy; membrane filtration; Membrane processes; Membranes; Membranes (Technology); molecular computation; nano-scale heterogeneity; Polyvinylidene fluoride; Polyvinylidene fluorides; Properties; Topology; Wettability; Singapore
• ISSN: 2077-0375; 2077-0375
• DOI: 10.3390/membranes12100977

Knowing the energetic topology of a surface is important, especially with regard to membrane fouling. In this study, molecular computations were carried out to determine the energetic topology of a polyvinylidene fluoride (PVDF) membrane with different surface wettability and three representative probe molecules (namely argon, carbon dioxide and water) of different sizes and natures. Among the probe molecules, water has the strongest interaction with the PVDF surface, followed by carbon dioxide and then argon. Argon, which only has van der Waals interactions with PVDF, is a good probing molecule to identify crevices and the molecular profile of a surface. Carbon dioxide, which is the largest probing molecule and does not have dipole moment, exhibits similar van der Waals and electrostatic interactions. As for water, the dominant attractive interactions are electrostatics with fluorine atoms of the intrinsically hydrophobic PVDF membrane, but the electrostatic interactions are much stronger for the hydroxyl and carboxyl groups on the hydrophilic PVDF due to strong dipole moment. PVDF only becomes hydrophilic when the interaction energy is approximately doubled when grafted with hydroxyl and carboxyl groups. The energetic heterogeneity and the effect of different probe molecules revealed here are expected to be valuable in guiding membrane modifications to mitigate fouling.