Electrocatalytic hydrogen production offers a promising solution to address current energy depletion. Herein, a RuNi/MoN heterostructure on carbon cloth (CC), RuNi/MoN@CC, was successfully constructed using a simple method, allowing for dual regulation of morphology and electronic structure. Under the influence of Ni, the in-situ generated MoN inherits the morphology of the NiMoO4 precursor, presenting a nanowire morphology, which is favorable for increasing electrochemical active area. Otherwise, the introduction of Ni acts as a sacrificial reducing agent and ensures that Ru remains in zero oxidation state as an electron donor to optimize the internal electronic distribution. Under the influence of dual regulation, the RuNi/MoN@CC requires only 66, 92, and 149 mV to achieve a current density of -10 mA cm-2 in alkaline, neutral, and acidic electrolytes, with the Tafel slopes of 50.4, 56.2, and 71.8 mV dec-1. This work will provide effective guidance for future exploration of transition metal-based catalysts suitable for a wide pH range.
Keywords: Dual regulation; Electronic interaction; Heterostructure; Morphology regulation; Wide pH range.
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