Chemical vapor deposition graphene transfer onto asymmetric PMMA support

Graphene is a promising material for membrane applications. However, the graphene production with large specific area and good structural quality is a challenge. Therefore, the production and characterization of composite membranes with graphene grown by chemical vapor deposition (CVD) over a porous polymethylmethacrylate (PMMA) substrate was investigated. The experimental strategy consisted in applying CVD‐graphene on a PMMA surface using PMMA‐assisted graphene wet transfer. The proposed methodology resulted in large‐area membranes with 2 cm diameter. The samples were characterized by Raman spectroscopy, indicating the presence of graphene in good quality and relative structural integrity. The analysis by scanning electron microscopy revealed the formation of a microporous support with an asymmetric structure. The gas permeation measurements of graphene/PMMA membranes showed a permeability reduction of 81.9% for CO2 and 83.7% for N2. The contribution of PMMA to flow resistance was 2% and 11% for CO2 and N2, respectively, and the contribution of graphene was 98% and 89% for CO2 and N2. Therefore, this research presents a potential advance in transferring graphene to porous support, and the impermeability process of membranes composed of graphene/PMMA, a fundamental step for the development of graphene membranes before the production of controlled‐sized pores. This research focused on the formation of composite membrane constituted by the superposition of thin film of PMMA and CVD‐Graphene on a porous substrate of PMMA. The objective was to evaluate the impermeability of the membrane, which is an important step for the production of a CVD‐Graphene‐based membrane.