Abstract
Improving the thermal and chemical stabilities of classical polymer membranes will be beneficial to extend their applications in the high temperature or aggressive environment. In this work, the asymmetric ultrafiltration membranes prepared from the polyacrylonitrile (PAN) were used to fabricate the cross-linking asymmetric (CLA) PAN membranes via thermal cross-linking in air to improve their thermal and chemical stabilities. The effects of thermal cross-linking parameters such as temperature and holding time on the structure, gas separation performance, thermal and chemical stabilities of PAN membranes were investigated by Fourier transform infrared spectroscopy (FTIR), X-ray photoelectron spectroscopy (XPS), positron annihilation lifetime spectroscopy (PALS), scanning electron microscopy (SEM), thermogravimetic analysis (TGA) and gas permeation test. The thermal cross-linking significantly influences the chemical structure, microstructure and pore structure of PAN membrane. During the thermal cross-linking, the shrinkage of membrane and coalescence or collapse of pore and microstructure make large pores diminish, small pores disappear and pore volumes reduce. The gas permeances of CLA-PAN membranes increase as the increasing of cross-linking temperature and holding time due to the volatilization of small molecules. The CLA-PAN membranes demonstrate excellent thermal and chemical stabilities and present good prospects for application in ultrafiltration for water treatment and for use as a substrate for nanofiltration or gas separation with an aggressive and demanding environment.
Highlights
Membrane-based separation technology as a novel and promising separation technology has been widely used to solve the problems on resources, energy and environment due to its high efficiency, low energy consumption and eco-friendliness [1,2]
The cross-linking asymmetric (CLA)-PAN membranes with favorable thermal and chemical stabilities were fabricated via thermal cross-linking in air
The pore structure of PAN membrane obviously changed during thermal cross-linking
Summary
Membrane-based separation technology as a novel and promising separation technology has been widely used to solve the problems on resources, energy and environment due to its high efficiency, low energy consumption and eco-friendliness [1,2]. Research work on the preparation of PAN cross-linking membranes [37,38] have been barely reported, especially those that investigated and discussed the effects of cross-linking parameters on the chemical, pore and microstructure, transport properties of PAN membranes. Thermal cross-linking was used to improve the thermal and chemical stabilities of PAN asymmetric membrane, which was prepared by dry-wet phase inversion technique. The motivation is to systematically investigate and discuss the effects of thermal cross-linking parameters such as temperature and holding time on the properties of PAN membranes, including the chemical, pore and microstructure, gas separation performance, thermal and chemical stabilities. Polymers 2018, 10, x FOR PEER REVIEW chemical and thermal stabilities of PAN membranes These works will be beneficial to prepare the cross-linking. For nanofiltration or gas separation with an aggressive and demanding environment
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