Tuning Structural Defects on a Nominal Single-Layered Graphene Oxide Membrane for Selective Separation of Biomolecules.

Abstract

Two-dimensional (2D) materials provide a great opportunity for fabricating ideal membranes with ultrathin thickness for high-throughput separation. Graphene oxide (GO), owing to its hydrophilicity and functionality, has been extensively studied for membrane applications. However, fabrication of single-layered GO-based membranes utilizing structural defects for molecular permeation is still a great challenge. Optimization of the deposition methodology of GO flakes could offer a potential solution for fabricating desired nominal single-layered (NSL) membranes that can offer a dominant and controllable flow through structural defects of GO. In this study, a sequential coating methodology was adopted for depositing a NSL GO membrane, which is expected to have no or minimum stacking of GO flakes and thus ensure GO's structural defects as the major transport pathway. We have demonstrated effective rejection of different model proteins (bovine serum albumin (BSA), lysozyme, and immunoglobulin G (IgG)) by tuning the structural defect size via oxygen plasma etching. By generating appropriate structural defects, similar-sized proteins (myoglobin and lysozyme; molecular weight ratio (MWR): ∼1.14) were effectively separated with a separation factor of ∼6 and purity of 92%. These findings may provide new opportunities of using GO flakes for fabricating NSL membranes with tunable pores for applications in the biotechnology industry.