RSC_Journal of Materials A
Factors in the utilization of corrosive ruthenium in the oxygen evolution electrode of polymer electrolyte membrane water electrolysis
The use of non-Pt materials in polymer electrolyte membrane water electrolysis (PEMWE) anodes is imperative to reduce green hydrogen production costs. Ru provides sufficient electrical and thermal conductivity, but rapidly over-oxidizes to RuO42− or H2RuO5 during PEMWE device operation. Therefore, this study involved using corrosive Ru instead of expensive Pt to form an interlayer between a Ti porous transport layer and the IrOx catalyst in PEMWE anodes, while enhancing the water-oxidation-catalyzing ability of IrOx. The optimized Ru-containing anode was comparable to the Pt-containing equivalent in OER performance (5.5 A cm−2 at 2.0 VCell; ∼80 μg cm−2 of Ir). Importantly, the Ru in the PEMWE anode functioned stably for >250 h at a practical current density (2.0 A cm−2) during current swing operation. Consequently, the Ru-interlayer-based device was comparable to the conventional Pt-interlayer-based counterpart in performance and durability. The relationship between Ru dissolution and local oxygen accumulation at electrode surfaces was clarified.
- Suji Lee
- Chaeyeon Yang
- Jihyun Choi
- Jong Hyun Jang
- Haneul Jin
- Yung-Eun Sung
- Hyun S. Park
https://pubs.rsc.org/en/content/articlelanding/2025/ta/d5ta01168j
RSC_Journal of Materials A
Factors in the utilization of corrosive ruthenium in the oxygen evolution electrode of polymer electrolyte membrane water electrolysis
The use of non-Pt materials in polymer electrolyte membrane water electrolysis (PEMWE) anodes is imperative to reduce green hydrogen production costs. Ru provides sufficient electrical and thermal conductivity, but rapidly over-oxidizes to RuO42− or H2RuO5 during PEMWE device operation. Therefore, this study involved using corrosive Ru instead of expensive Pt to form an interlayer between a Ti porous transport layer and the IrOx catalyst in PEMWE anodes, while enhancing the water-oxidation-catalyzing ability of IrOx. The optimized Ru-containing anode was comparable to the Pt-containing equivalent in OER performance (5.5 A cm−2 at 2.0 VCell; ∼80 μg cm−2 of Ir). Importantly, the Ru in the PEMWE anode functioned stably for >250 h at a practical current density (2.0 A cm−2) during current swing operation. Consequently, the Ru-interlayer-based device was comparable to the conventional Pt-interlayer-based counterpart in performance and durability. The relationship between Ru dissolution and local oxygen accumulation at electrode surfaces was clarified.
https://pubs.rsc.org/en/content/articlelanding/2025/ta/d5ta01168j