Infiltration of 40SiO2−40P2O5−20ZrO2 sol-gel in sSEBS membranes for PEMFCs application

This work describes the preparation of novel and low cost hybrid organic-inorganic membranes via sol-gel chemistry and direct infiltration method using a novel inorganic precursor (40SiO2−40P2O5−20ZrO2) and sulfonated styrene-ethylene-butylene-styrene triblock copolymer (sSEBS) for their use in fuel...

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Bibliographic Details
Published in:Journal of membrane science 2018-04, Vol.551, p.136-144
Main Authors: Escribano, P.G., del Río, C., Morales, E., Aparicio, M., Mosa, J.
Format: Article
Language:English
Subjects:
Infiltrated membranes
Phosphosilicate
Proton exchange membrane
Sol-gel hybrids
Sulfonated SEBS
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Summary:This work describes the preparation of novel and low cost hybrid organic-inorganic membranes via sol-gel chemistry and direct infiltration method using a novel inorganic precursor (40SiO2−40P2O5−20ZrO2) and sulfonated styrene-ethylene-butylene-styrene triblock copolymer (sSEBS) for their use in fuel cells (PEMFC). sSEBS shows a distinct phase separated morphology which can be used as a template to incorporate the inorganic component preferentially within the ionic domains of the polymer, improving mechanical stability and reducing water uptake. The hybrid membranes are evaluated and compared to sSEBS in terms of swelling in water, IEC and FTIR. Chemical oxidation stability has been investigated using Fenton's reagent and the morphology has been observed using FE-SEM, EDX and AFM. The electrochemical characterization in single cells was carried out at 60 °C, atmospheric pressure and 100% relative humidity in order to determine hydrogen crossover, through-plane proton conductivity and cell performance. The results show that infiltration times up to 40 min lead to hybrid membranes with lower swelling in water, enhanced dimensional stability, good proton conductivity and better cell performance than pure sSEBS. •Infiltrated phosphosilicate-sSEBS membranes are properly prepared by sol-gel method.•Incorporation of the inorganic phase into hydrophilic domains is confirmed by FTIR.•Infiltration induces strong hydrogen bond interactions between Si-OH, P-OH and SO3H.•Short time infiltrated hybrid membranes exhibit higher power density than sSEBS.•Best cell performance is reported for the hybrid membrane infiltrated for 10 min.
ISSN:0376-7388
1873-3123
DOI:10.1016/j.memsci.2018.01.044