Based on recent theoretical studies, we designed a multistep experimental protocol to understand the impact of environmental conditions around Pt nanodeposits on Membrane chemical degradation. The first experiment probes the local potential at a Pt microelectrode for different rates of permeation of hydrogen and oxygen gases from anode and cathode side. The subsequent degradation experiment utilizes the local conditions taken from the first experiment to analyze local rates of ionomer degradation. The rate of ionomer decomposition is significantly enhanced in the anodic H2-rich membrane region, which can be explained with the markedly increased amount of H2O2 formation at Pt nanodeposits in this region
Platinum is the most used electrocatalyst in proton exchange membrane fuel cells (PEMFCs). Nonethele...
In polymer electrolyte fuel cells, a foremost goal is to design catalyst layers with high performanc...
One of the main sources of membrane degradation in fuel cells is attack by radicals formed wherever ...
The impact of the Pt band on ionomer degradation is controversial. Many studies found increased degr...
Formation of hydrogen peroxide and oxygenated radical species are the leading cause of chemical degr...
The research examined possible sources of degradation of platinum based anode catalysts under long t...
Governments and industries are pursuing the use of green hydrogen to achieve zero emissions, especia...
The function of catalytic layers in fuel cells and electrolyzers depends on the properties of the io...
A remaining challenge for deployment of proton-exchange membrane fuel cells is the limited durabili...
One of the main sources of membrane degradation in fuel cells is attack by radicals formed wherever ...
Durability of carbon-supported platinum nanoparticle is one of the limiting factors for PEM fuel cel...
Platinum is the state-of-the-art catalyst for hydrogen evolution in polymer electrolyte membrane (PE...
The goal of this PhD research is to fundamentally understand the degradation mechanisms and durabili...
The major source of membrane chemical degradation during proton exchange membrane fuel cell operatio...
DoctorThe distribution patterns of Pt crystals that have moved from electrodes to the membrane phase...
Platinum is the most used electrocatalyst in proton exchange membrane fuel cells (PEMFCs). Nonethele...
In polymer electrolyte fuel cells, a foremost goal is to design catalyst layers with high performanc...
One of the main sources of membrane degradation in fuel cells is attack by radicals formed wherever ...
The impact of the Pt band on ionomer degradation is controversial. Many studies found increased degr...
Formation of hydrogen peroxide and oxygenated radical species are the leading cause of chemical degr...
The research examined possible sources of degradation of platinum based anode catalysts under long t...
Governments and industries are pursuing the use of green hydrogen to achieve zero emissions, especia...
The function of catalytic layers in fuel cells and electrolyzers depends on the properties of the io...
A remaining challenge for deployment of proton-exchange membrane fuel cells is the limited durabili...
One of the main sources of membrane degradation in fuel cells is attack by radicals formed wherever ...
Durability of carbon-supported platinum nanoparticle is one of the limiting factors for PEM fuel cel...
Platinum is the state-of-the-art catalyst for hydrogen evolution in polymer electrolyte membrane (PE...
The goal of this PhD research is to fundamentally understand the degradation mechanisms and durabili...
The major source of membrane chemical degradation during proton exchange membrane fuel cell operatio...
DoctorThe distribution patterns of Pt crystals that have moved from electrodes to the membrane phase...
Platinum is the most used electrocatalyst in proton exchange membrane fuel cells (PEMFCs). Nonethele...
In polymer electrolyte fuel cells, a foremost goal is to design catalyst layers with high performanc...
One of the main sources of membrane degradation in fuel cells is attack by radicals formed wherever ...