Roham Solasi scite author profile

The life of proton exchange membrane fuel cells (PEMFC) is currently limited by the mechanical endurance of polymer electrolyte membranes and membrane electrode assemblies (MEAs). In this paper, the authors report recent experimental and modeling work toward understanding the mechanisms of delayed mechanical failures of polymer electrolyte membranes and MEAs under relevant PEMFC operating conditions. Mechanical breach of membranes/MEAs in the form of pinholes and tears has been frequently observed after long-term or accelerated testing of PEMFC cells/stacks. Catastrophic failure of cell/stack due to rapid gas crossover shortly follows the mechanical breach. Ex situ mechanical characterizations were performed on MEAs after being subjected to the accelerated chemical aging and relative humidity (RH) cycling tests. The results showed significant reduction of MEA ductility manifested as drastically reduced strain-to-failure of the chemically aged and RH-cycled MEAs. Postmortem analysis revealed the formation and growth of mechanical defects such as cracks and crazing in the membranes and MEAs. A finite element model was used to estimate stress/strain states of an edge-constrained MEA under rapid RH variations. Damage metrics for accelerated testing and life prediction of PEMFCs are discussed.

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On mechanical behavior and in-plane modeling of constrained PEM fuel cell membranes subjected to hydration and temperature cycles

Solasi

Zou

Huang

et al. 2007

Journal of Power Sources

128

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A time and hydration dependent viscoplastic model for polyelectrolyte membranes in fuel cells

Solasi

Zou

Huang

et al. 2007

Mech Time-Depend Mater

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Multi-scale modeling approaches for functional nano-composite materials

Reifsnider

Huang

et al. 2006

J Mater Sci

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Creep and stress-rupture of Nafion® membranes under controlled environment

Solasi

Huang

Reifsnider

2010

Mechanics of Materials

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Roham Solasi

Mechanical endurance of polymer electrolyte membrane and PEM fuel cell durability

On mechanical behavior and in-plane modeling of constrained PEM fuel cell membranes subjected to hydration and temperature cycles

A time and hydration dependent viscoplastic model for polyelectrolyte membranes in fuel cells

Multi-scale modeling approaches for functional nano-composite materials

Creep and stress-rupture of Nafion® membranes under controlled environment

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