Catalyst Degradation Mitigation and Fuel Utilization Enhancement of a Dead-Ended Anode and Cathode Proton Exchange Membrane Fuel Cell with Periodical Oxygen Supply

Abstract: Hydrogen−oxygen proton exchange membrane fuel cells (PEMFCs) have promising military applications. However, carbon corrosion in the catalyst layer induced by water flooding significantly affects the performance and longevity of PEMFCs. In this study, a periodical oxygen supply strategy is proposed to improve water management in PEMFCs. The hydrogen and oxygen utilization reached 99.84 and 98.82%, respectively. The performance degradation rate of a PEMFC with a current density of 600 mA•cm −2 decreased by 45.1%… Show more

“…As a kind of alternative power generation device, hydrogen–oxygen fuel cells have received extensive attention due to their high energy conversion efficiency and excellent environmental compatibility. 1–3 At the two ends of the cells, oxygen reduction reaction (ORR) and hydrogen oxidation reaction (HOR) take place. Both ends need catalysts to effectively drive the reduction and oxidation processes.…”

Ir/Ni–NiO/CNT composites as effective electrocatalysts for hydrogen oxidation

“…As a kind of alternative power generation device, hydrogen–oxygen fuel cells have received extensive attention due to their high energy conversion efficiency and excellent environmental compatibility. 1–3 At the two ends of the cells, oxygen reduction reaction (ORR) and hydrogen oxidation reaction (HOR) take place. Both ends need catalysts to effectively drive the reduction and oxidation processes.…”

Ir/Ni–NiO/CNT composites as effective electrocatalysts for hydrogen oxidation

“…13,14 Another crucial issue is to carefully adjust the adsorption strength of H ad and OH ad to an optimal level simultaneously. [15][16][17] Supported metal nanoclusters with a particle size less than 3 nm demonstrate improved catalytic efficacy because of their unique geometry, electronic structure, and synergistic interaction with the support material. 16 These nanoclusters also demonstrate high atomic utilization efficiency, exposing more active atoms than their nanoparticle counterparts, thereby providing a multitude of active sites for adsorption and activation of diverse intermediates.…”

“…[15][16][17] Supported metal nanoclusters with a particle size less than 3 nm demonstrate improved catalytic efficacy because of their unique geometry, electronic structure, and synergistic interaction with the support material. 16 These nanoclusters also demonstrate high atomic utilization efficiency, exposing more active atoms than their nanoparticle counterparts, thereby providing a multitude of active sites for adsorption and activation of diverse intermediates. 16,17 The abundant (near-)interface metal atoms within these nanoclusters play a crucial role in optimizing adsorption behaviors across multiple reaction steps.…”

“…16 These nanoclusters also demonstrate high atomic utilization efficiency, exposing more active atoms than their nanoparticle counterparts, thereby providing a multitude of active sites for adsorption and activation of diverse intermediates. 16,17 The abundant (near-)interface metal atoms within these nanoclusters play a crucial role in optimizing adsorption behaviors across multiple reaction steps. This can be effectively modulated by metal-support interactions, including interfacial charge transfer.…”

“…13,14 Another crucial issue is to carefully adjust the adsorption strength of H ad and OH ad to an optimal level simultaneously. 15–17…”

A trinary support of Ni/NiO/C to immobilize Ir nanoclusters for alkaline hydrogen oxidation

Platinum Dissolution and Ionomer Redistribution/Degradation in Fuel Cells—An Evaluation