Abstract

Abstract Rational design of efficient pH‐universal hydrogen evolution reaction catalysts to enable large‐scale hydrogen production via electrochemical water splitting is of great significance, yet a challenging task. Herein, Ru atoms in the Ru 2 P structure were replaced with M = Co, Ni, or Mo to produce M 2− x Ru x P nanocrystals. The metals show strong site preference, with Co and Ni occupying the tetrahedral sites and Ru the square pyramidal sites of the CoRuP and NiRuP Ru 2 P‐type structures. The presence of Co or Ni in the tetrahedral sites leads to charge redistribution for Ru and, according to density functional theory calculations, a significant increase in the Ru d‐band centers. As a result, the intrinsic activity of CoRuP and NiRuP increases considerably compared to Ru 2 P in both acidic and alkaline media. The effect is not observed for MoRuP, in which Mo prefers to occupy the pyramidal sites. In particular, CoRuP shows state‐of‐the‐art activity, outperforming Ru 2 P with Pt‐like activity in 0.5 M H 2 SO 4 ( η 10 = 12.3 mV; η 100 = 52 mV; turnover frequency (TOF) = 4.7 s −1 ). It remains extraordinarily active in alkaline conditions ( η 10 = 12.9 mV; η 100 = 43.5 mV) with a TOF of 4.5 s −1 , which is 4x higher than that of Ru 2 P and 10x that of Pt/C. Further increase in the Co content does not lead to drastic loss of activity, especially in alkaline medium, where, for example, the TOF of Co 1.9 Ru 0.1 P remains comparable to that of Ru 2 P and higher than that of Pt/C, highlighting the viability of the adopted approach to prepare cost‐efficient catalysts.