Gas Permeation Properties of Amorphous SiC Membranes Synthesized from Polycarbosilane without Oxygen-Curing Process

Abstract

Amorphous silicon carbide (SiC) membranes with molecular sieving properties were successfully synthesized on the outer surface of a γ-alumina (γ-Al₂O₃)-coated α-alumina (α-Al₂O₃) porous support through pyrolysis of polycarbosilane without oxygen-curing process. The amorphous SiC membrane pyrolyzed at 1073 K after dip coating with capillary force possessed the hydrogen (H₂) permeance of 8.1×10^-7 mol•m^-2•s^-1•Pa^-1 and the H₂/carbon dioxide (CO₂) permselectivity of 13 at 873 K. On the other hand, the amorphous SiC membrane pyrolyzed at 1073 K a total of four times after dip coating without capillary force possessed a helium (He) permeance of 2.4×10^-7 mol•m^-2•s^-1•Pa^-1, a He/H₂ permselectivity of 1.9 and a He/CO₂ permselectivity of 19 and at 873 K. Gas permeance properties were depended on coating method, densification of the Si-C network by heat history and film thickness.