Rubbery
polymer membranes prepared from CO2-philic PEO
and/or highly permeable PDMS are desired for efficient CO2 separation from light gases (CH4 and N2).
Poor mechanical properties and size-sieving ability, however, limit
their application in gas separation applications. Cross-linked rubbery
polymer-based gas separation membranes with a low T
g based on both PEG/PPG and PDMS units with various compositions
between these two units are prepared for the first time in this work
by ring-opening metathesis polymerization type cross-linking and in
situ membrane casting. The developed membranes display excellent CO2 separation performance with CO2 permeability ranging
from 301 to 561 Barrer with excellent CO2/N2 selectivity ranging from 50 to 59, overcoming the Robeson upper
bound (2008). The key finding underlying the excellent performance
of the newly developed cross-linked x(PEG/PPG:PDMS)
membranes is the formation of a well-connected interlocked network
structure, which endows the rubbery materials with the properties
of rigid polymers, e.g., size-sieving ability and high thermomechanical
stability. Moreover, the membrane shows long-term antiaging performance
of up to eight months and antiplasticization behavior up to 25 atm
pressure.
We
report semi-interpenetrating polymer network (semi-IPN) membranes
prepared easily from a cross-linked network using poly(acrylic acid)
(PAA) and poly(vinyl alcohol) (PVA) with interpenetrated Nafion for
both proton-exchange membrane fuel cell (PEMFC) and proton-exchange
membrane water electrolyzer (PEMWE) applications. Thermal esterification
between PAA and PVA induced three-dimensional cross-linking to improve
mechanical toughness and reduce hydrogen crossover, while the hydrophilic
nature of the PAA–PVA-based cross-linked matrix still enhanced
the water uptake (WU) and hence conductivity of the Nafion penetrant.
The semi-IPN membrane (NPP-95) composed of Nafion, PAA, and PVA with
a ratio of 95:2.5:2.5 showed a hexagonal cylindrical morphology and
improved thermal, mechanical, and dimensional stability compared to
a recast Nafion membrane (re-Nafion). The membrane was also highly
effective at managing water due to its low WU and high conductivity.
Furthermore, its hydrogen permeability was 49.6% lower than that of
re-Nafion under the actual fuel cell operating conditions (at 100%
RH and 80 °C). NPP-95 exhibited significantly improved conductivity
and PEMFC performance compared to re-Nafion with a current density
of 1561 mA/cm2 at a potential of 0.6 V and a peak power
density of 1179 mW/cm2. Furthermore, in the PEMWE performances,
NPP-95 displayed about a 1.5-fold higher current density of 4310 mA/cm2 at 2.0 V and much lower ohmic resistance than re-Nafion between
60 and 80 °C.
Poly(2,4-phenylene oxide)s (PPOs)-based anion exchange membranes (AEMs) with four of the most widely investigated head groups were prepared. Through a combination of experimental and simulation approaches, the effects of the different types of head groups on the properties of the AEMs, including hydroxide conductivity, water content, physicochemical stability, and fuel cell device performance were fully explored. Unlike other studies, in which the conductivity was mostly investigated in liquid water, the conductivity of the PPObased AEMs in 95% relative humidity (RH) conditions as well as in liquid water was investigated. The conductivity trend in 95% RH condition was different from that in liquid water but corresponded well with the actual cell performance trend observed, suggesting that the AEM fuel cell performance under in situ cell conditions (95% RH, 60 °C, H 2 /O 2 ) is more closely related to the conductivity measured ex situ under 95% RH conditions (60 °C) than in liquid water. On the basis of the conductivity data and molecular simulation results, it was concluded that the predominant hydroxide ion-conducting mechanism in liquid water differs from that in the operating fuel cell environment, where the ionomers become hydrated only as a result of water vapor transported into the cells.
Nafion, as a perfluorosulfonic acid (PFSA)-based polymer, is a key material that contributes to the commercialization of proton exchange membrane fuel cells (PEMFCs). The high dependence on relative humidity (RH) of Nafion or other PFSA membranes for proton conduction, together with its decreased mechanical and dimensional stability and high fuel (H 2 ) crossover at the cell operating temperatures (80 °C or above), however, remain issues that have yet to be solved. In the current work, thin sulfonated poly(arylene ether sulfone) (sPES)-coated Nafion membranes (sPES-c-Nafions) are developed, for the first time, by simply spin-coating the sPES solution onto a Nafion membrane, and the results are compared with the sPES-blended Nafion counterparts. The sPES-c1-Nafion demonstrates a very high proton conductivity of 223.3 mS cm −1 (80 °C) and a very low hydrogen permeability, a 41% reduction compared to that of Nafion-212, together with improved mechanical and dimensional stabilities compared to Nafion-212. The developed membrane also shows excellent cell performance (i.e., with a current density of 1.56 A cm −2 and a peak power density of 1.20 W cm −2 at 0.6 V potential in the actual operating conditions of PEMFCs).
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