Electrocatalytic water splitting is a possible route to the expanded generation of green hydrogen however a long-term challenge is the requirement of fresh water as an electrolyzer feed. The use of seawater as a direct feed for electrolytic hydrogen production would alleviate fresh water needs and potentially open an avenue for locally generated hydrogen from marine hydrokinetic or off-shore power sources. One environmental limitation to seawater electrolysis is the generation of chlorine as a competitive anodic reaction. This work evaluates transition metal (W, Co, Fe, Sn and Ru) doping of Mn-Mo based catalysts as a strategy to suppress chlorine evolution while sustaining catalytic efficiency. Electrochemical evaluations in neutral chloride solution and raw seawater showed the promise of a novel Mn-Mo-Ru electrode system for oxygen evolution effi-ciency and enhanced catalytic activity. Subsequent stability testing in a flowing raw seawater flume highlighted the need for improved catalyst stability for long-term applications of Mn-Mo-Ru catalysts. This work highlights that elements known to be selective toward chlorine evolution in simple-oxide form (e.g. RuO2) may display different trends in selectivity when used as isolated dopants, where here Ru suppressed chlorine evolution in Mn-based catalysts. Adiga P.P., N. Doi, D.M. Santosa, L. Kuo, G.A. Gill, J.A. Silverstein, and N.M. Avalos, et al. 2021. “The Influence of Transitional Metal Dopants on Reducing Chlorine Evolution During the Electrolysis of Raw Seawater.” Applied Sciences. PNNL-SA-165321. [Unpublished]
