Researchers from the Institute of Process Engineering (IPE) of the Chinese Academy of Sciences, Argonne National Laboratory (Argonne), and the University of Chicago in the U.S. have searched and summarized recent developments in the field of nanofiltration (NF), and provided guidance for potential future approaches to improve the selectivity of nanofiltration membranes.

The study was published on ACS Applied Materials & Interfaces on August 12 (DOI: 10.1021/acsami.0c11136).

Water filtration membranes have been widely applied in water treatment facilities, semiconductor manufacturing sites, and within the food and beverage industry, due to its competitive cost and effectiveness.

NF membranes have attracted lots of attention as they can efficiently separate monovalent and multivalent ions and precisely separate small organic molecules with different molecular weights. The global market for NF membranes is projected to grow almost 20% annually, reaching 1.2 billion dollars by 2024.

However, most investigations involving NF membranes focus on improvement of membrane permeance, leaving selectivity behind. In an energy preservation point, it is of great importance to increase selectivity among NF membranes.

In the study, the researchers overviewed the latest strategies for NF membrane selectivity improvement comprehensively. They concentrated on membrane fabrication approaches including pore size or pore-size distribution adjustment, charge distribution manipulation, and surface anti-fouling modification. Then they emphasized on studies on function/process-intensified-NF for enhancing NF membrane performance.

They also offered perspectives on potential opportunities in future research. NF selectivity would be rooted in engineering of membrane interfacial properties, which underlie both advantageous properties such as surface charge for electrostatic rejection and deleterious properties such as propensity to fouling. Innovation in operating processes also play a key role in improving the selectivity of nanofiltration membranes, as transmembrane pressure, pH, and recycling ratio of feed solution during operation processes affect the selectivity.

"The article would facilitate the future investigations in separation selectivity of NF membranes, and the researchers would pay more attention on this important issue," said Prof. LUO Jianquan from IPE.

Dr. Seth B. Darling, a co-author from Argonne, noted that this review "shed light on cutting edge developments in selectivity in NF membranes, and no doubt would encourage more researchers participating in this exciting filed."

Schematic diagram of Strategies for enhancing selectivity of NF membranes (a-c) during membrane fabrication or (d-f) through function or process intensification (Image by ZHANG Huiru)

Media Contact: 
LI Xiangyu
Public Information Officer
Institute of Process Engineering, Chinese Academy of Sciences, Beijing 100190, P. R. China. 
E-mail: xiangyuli@ipe.ac.cn
Tel: 86-10-82544826