Selective Catalyst Surface Access through Atomic Layer Deposition

Catalyst poisoning is a prominent issue, reducing the lifetime of catalysts and increasing the costs of the processes that rely on them. The electrocatalysts that enable green energy conversion and storage, such as proton exchange membrane fuel cells and hydrogen bromine redox flow batteries, also suffer from this issue, hindering their utilization. Current solutions to protect electrocatalysts from harmful species fall short of effective selectivity without inhibiting the required reactions. This article describes the protection of a standard 50% Pt/C catalyst with a V2O5 coating through atomic layer deposition (ALD). The ALD selectively deposited V2O5 on the Pt, which enhanced hydrogen transport to the Pt surface and resulted in a higher mass activity in alkaline electrolytes. Cyclic voltammetry and X-ray photoelectron spectroscopy showed that the Pt was protected by the coating in the HBr/Br-2 electrolyte which dissolved the uncoated SO% Pt/C in under 3 min.

Automated summary

The article discusses the issue of catalyst poisoning and presents a solution using V2O5 coating deposited through atomic layer deposition to protect Pt/C catalysts. The coating selectively enhances hydrogen transport to the Pt surface, resulting in higher mass activity in alkaline electrolytes and protection from harmful species like HBr/Br-2.