In situ visualization of combined membrane fouling behaviors using multi-color light sheet fluorescence imaging: A study with BSA and dextran mixture

Abstract

The understanding of fouling behaviors and mechanism is critical for membrane fouling that is a bottleneck for the sustainable application of membrane technology. Therefore, it is essential to develop new analytical tools that can in situ characterize membrane fouling processes during filtration. In this work, we demonstrate a capability of high-resolution large-scale in situ visualization that can rapidly differentiate foulants and their temporal-spatial-distributions on/in/over the membrane matrix during filtration process based on multi-color light sheet fluorescence imaging platform. The rapid-evolving fouling process of different foulants were directly monitored and analyzed during the ultrafiltration of bovine serum albumin (BSA), dextran and their mixture solutions. Inner adsorption was found to play a more critical role for dextran-induced fouling on polymeric membranes compared with BSA-induced fouling. During the ultrafiltration of BSA/dextran mixture solutions, BSA was directly observed as the major contributor to the decrease of permeate flux, which could be employed as a complementary evidence for the interfacial free energy calculations during membrane fouling and vice versa. This work provides new insights into combined membrane fouling process and offers a highly-sensitive, non-invasive characterization tool for a wide range of explorations in membrane-based processes and interfacial processes. In situ large-scale characterization of combined membrane fouling behaviors Strong relations between flux decline rate and foulant distributions in/on membrane Direct observation of key foulant in combined fouling process Facilitation of exploring interfacial processes (dynamic and thermodynamic)