posted on 2015-07-29, 00:00authored byYuanyuan Wang, Hongyu Li, Guangxi Dong, Colin Scholes, Vicki Chen
Poly(ethylene
oxide)- (PEO-) based block copolymer membranes have
great potential for use in CO2 separation because of their
excellent selectivity and moderate permeability. Whereas numerous
studies have focused on the permeation performance of such membranes,
the influence of the microphase-separated structures on the gas transport
is not well understood. This study examined the phase structure of
PEO–polyamide (PA) (commercial name, Pebax) block copolymer
membranes by scanning probe microscopy (SPM) imaging and thermal analysis.
The membranes with the irregular and more disordered phase-separated
structure, such as Pebax-1074 membranes, that had longer PA chains
and were made using a faster sol-to-gel transition process resulted
in higher CO2 permeability than the membranes with the
more ordered phase structure. The CO2 solubility coefficient
profile as a function of pressure in the Pebax membranes with dual-mode
sorption characteristics indicated the involvement of a glassy hard
phase in CO2 transport, particularly at low pressure. The
effects of temperature on gas transport and separation performance
for a CO2/N2 gas mixture were also investigated.