Experimental investigation of the transport mechanism of several gases during the CVD post-treatment of nanoporous membranes

•Ceramic membranes were modified by applying a cyclic mode of CVD process.•a-Alumina/silica tubes with a separation layer of 1 nm pore size were used as substrates.•The substrates’ pore structure evolution during the CVD processes was investigated.•The permeance of He and N2 gases with the progress of silica deposition was monitored.•The permeation properties of the treated membranes were evaluated using several probe gases.

The current study stresses the importance of combining gas transport theories with experimental gas permeability results on the effort to elucidate nanopore structure evolution of nanofiltration membranes during their modification through the chemical vapour deposition technique. To this end, silica membranes of 1 nm nominal pore size were post-treated by applying a sequential cyclic CVD method at 573 K and the Tetraethyl-orthosilicate/Ozone reaction system. Alteration of the gas transport characteristics was investigated by conducting single gas permeance measurements of Helium and Nitrogen at selected temperatures following the completion of several CVD cycles. The experimental results were interpreted on the basis of gas transport theories combined with a model for the evolution of pore size distribution of the membrane’s separation layer during silica deposition. By monitoring permeation properties of the treated membranes with the progress of deposition using Helium and Nitrogen as probe gases, optimized treatment conditions can be established in order to fabricate selective and highly permeable – with respect to Hydrogen gas – ceramic membranes. Furthermore, the dependence of the permeation properties on the pore size of the studied membranes before and after their CVD treatment was investigated by performing single-gas permeance measurements of several probe gases within a wide temperature range.