The Effect of C/Si Ratio and Fluorine Doping on the Gas Permeation Properties of Pendant-Type and Bridged-Type Organosilica Membranes

A series of pendant-type alkoxysilane structures with various carbon numbers (C-1-C-8) were used to fabricate sol-gel derived organosilica membranes to evaluate the effects of the C/Si ratio and fluorine doping. Initially, this investigation was focused on the effect that carbon-linking (pendant-type) units exert on a microporous structure and how this affects the gas-permeation properties of pendant-type organosilica membranes. Gas permeation results were compared with those of bridged-type organosilica membranes (C-1-C-8). Network pore size evaluation was conducted based on the selectivity of H-2/N-2 and the activation energy (E-p) of H-2 permeation. Consequently, E-p (H-2) was increased as the C/Si ratio increased from C-1 to C-8, which could have been due to the aggregation of pendant side chains that occupied the available micropore channel space and resulted in the reduced pore size. By comparison, these permeation results indicate that pendant-type organosilica membranes showed a somewhat loose network structure in comparison with bridged-type organosilica membranes by following the lower values of activation energies (E-p). Subsequently, we also evaluated the effect that fluorine doping (NH4F) exerts on pendant-type [methytriethoxysilane (MTES), propyltrimethoxysilane (PTMS)] and bridged-type [1,2-bis(triethoxysilyl)methane (BTESM) bis(triethoxysilyl)propane (BTESP)] organosilica structures with similar carbon numbers (C-1 and C-3). The gas-permeation properties of F-doped pendant network structures revealed values for pore size, H-2/N-2 selectivity, and E-p (H-2) that were comparable to those of pristine organosilica membranes. This could be ascribed to the pendant side chains, which might have hindered the effectiveness of fluorine in pendant-type organosilica structures. The F-doped bridged-type organosilica (BTESM and BTESP) membranes, on the other hand, exhibited a looser network formation as the fluorine concentration increased.

Automated summary

The effects of carbon number and fluorine doping on the structure and gas permeation properties of organosilica membranes were investigated. The results showed that carbon number and fluorine doping could alter the pore structure of the membranes and affect their gas permeation properties.