Proton exchange membrane (PEM)-based water-splitting electrolyzers have been considered as the most promising hydrogen production technology with great advantages including low Ohmic loss, high electrolyzer efficiency, and large partial load range. [1] However, most developed non-noble metal-based hydrogen/oxygen evolution electrocatalysts are usually not stable in the severe corrosive acidic environment in PEM electrolyzers, [2] which makes the utilization of noble metal indispensable. Moreover, the overall energy conversion efficiency of water-splitting devices is greatly depended on the activity of catalysts both at cathode and anode. [1,3] Therefore, developing electrocatalysts with high activity and corrosion resistant at minimized noble metal content is of great significance toward large-scale hydrogen generation through PEM electrolyzers.Among all the noble metals, Ir-based materials have been regarded as the efficient oxygen evolution reaction (OER) catalysts for their superior activity as well as stability in acidic media. [4] In addition, recent works also indicate the potential of Ir as good catalysts toward hydrogen evolution reaction (HER), even comparable to Pt. [5] Unfortunately, the further application of Ir still suffers from its high cost and scarcity, which greatly limits the widespread adoption of PEM electrolysis. Modulating the nanostructure of catalysts with high surface area stands for one of effective methods to improve the atomic utilization. [6] A series of different Ir-based nanostructures, such as nanoparticles, [7] porous/laminar nanosheets, [8] nanowires, [9] nanotubes, [10] etc., have been reported with enhanced catalytic activity. Among these various shape-controlled nanostructures, 3D flower-like architectures are equipped with abundant catalytic sites, meanwhile have antiaggregation properties in the drastic reaction. [11] Furthermore, alloying Ir with other 3d transition metals is the other valid strategy to decrease the content as well as increase the intrinsic activity of Ir. [12] In these cases, the optimized adsorption energy on the catalysts has been obtained with modified electronic distribution through alloying. However, as for HER on Ir-based alloy, though similar promotion on the catalytic activity compared with Ir metal has been reported, [13] the HER descriptor could be attributed to the hydrogen binding energy (HBE) in acidic solution. [14] The internal relationship Hydrogen production through proton exchange membrane water electrolyzers (PEMWE) requires more active and stable electrocatalysts in acidic media. Herein, a class of Ir-based alloys is reported with flower-like structure as excellent electrocatalysts both for hydrogen and oxygen generation in acid. Specially, the IrNi alloy nanoflowers (IrNi NFs) present the best hydrogen evolution reaction (HER) performance, revealed by a low Tafel slope and overpotential at current density of 10 mA cm −2 , exceeding the commercial Pt/C. It is discovered that alloying Ir with Ni can decrease the hydrogen binding e...
