Phase-Tailored RuNi Alloys with Dual-Site Synergistic Catalysis for Stable Alkaline Water Electrolysis
Shihuan Hong, Ning Song, Zhiqiang Zhang, Hongjun Dong, Min Zhang, Yangyang Yu, Chunmei Li, Weidong Shi
Abstract
Phase tailoring engineering of two-dimensional RuNi alloys was achieved via a host–guest exchange strategy, which endowed oxygen evolution reaction (OER) activity exceeding that of RuO 2 to the RuNi (40:250) alloy with an fcc -Ni host and hcp -Ru guest as well as hydrogen evolution reaction (HER) activity exceeding that of Pt/C to the RuNi (250:40) alloy with an fcc / hcp -Ru host and fcc -Ni guest. X-ray photoelectron spectroscopy and in situ shell-isolated nanoparticle-enhanced Raman spectroscopy revealed that their differentiated surface reconstruction induced the respective two-site synergistic catalytic effect. The hcp -Ru site in the RuNi (40:250) alloy catalyzed the oxidation of OH – ions to O–O* and then generated a bridge-mode configuration of Ru–O–O–Ni by coupling with the adjacent Ni site to facilitate O 2 evolution, while the fcc -Ru site in the RuNi (250:40) alloy acted as a transfer station for H 2 O by forming a Ru–OH 2 adsorption state, followed by fabricating a bridge-mode configuration of Ru–HO–H–Ni through connection with the adjacent Ni site to promote H 2 O dissociation and H 2 evolution. The integrated RuNi (40:250) || RuNi (250:40) electrolyzer achieved overall water splitting at 1.49 V (10 mA cm –2 ), outperforming the Pt/C || RuO 2 benchmark (1.54 V), and stable operation for 650 h. This work provides fresh insights into phase-dependent dual-site synergistic catalytic behaviors for advanced alloy catalysts.