Selective reduction of epoxy groups in graphene oxide membrane for ultrahigh water permeation

Permeation of graphene oxide (GO) membranes is expected to improve significantly when epoxy groups are removed while retaining hydroxyl groups in the GO flakes. However, it is still difficult for conventional reduction methods to achieve such selective reduction of oxygen-containing groups. In this paper, we demonstrated the precise selective reduction of GO flakes with low epoxy content but high hydroxyl content using modified electron beam irradiation (EBI). Remarkably, membranes prepared with the reduced GO flakes (EBI-rGO) have ultrahigh water permeation from 92.7 to 267.1 L m(-2) h(-1) bar(-1) while still maintaining the effective rejection rates for both dyes (methyl blue, pararosaniline and rhodamine B) and multivalent metal ions (Fe3+, Pb2+ and Cu2+). Theoretical calculations show that newly generated hydroxyl, obtained by reducing epoxy using the hydrogen radical (H center dot), plays an important role in controlling selective reduction. Our study provides an effective way to fabricate GO membranes with outstanding water purification performance. (C) 2020 Elsevier Ltd. All rights reserved.

Automated summary

This study demonstrates the precise selective reduction of graphene oxide (GO) flakes with low epoxy content but high hydroxyl content using modified electron beam irradiation (EBI), leading to the fabrication of GO membranes with ultrahigh water permeation and effective rejection of dyes and multivalent metal ions. New hydroxyl groups generated by reducing epoxy using hydrogen radicals play a key role in controlling selective reduction and enhancing water purification performance of the membranes.