Constructing multilevel structure with microdomains of oxides on Three-Dimensional High-Entropy alloy support toward efficient oxygen evolution

High-entropy alloy (HEA) with maximized configurational entropy has shown a great promise for anodic water splitting, but still limited to their unsatisfactory configuration and large-scaled application. In the present study, a series of dual-phase electrodes with spinel MnCr2O4 microdomains pinning on large-scaled and flexible surface oxidized high-entropy alloys (O-HEA) as highly efficient electrocatalysts is prepared by combining modified non-solvent induced phase separation (NIPs) and metallurgy approaches. The precipitation of MnCr2O4 microdomains from HEA support not only result in a shrinking of lattice constant, but also lead to a surface reconstruction. Besides, the MnCr2O4 microdomains can synergy with reconstructed O-HEA support to increase the hydrophilic property and provide high-efficient electron/ion transport, thus promoting the oxygen evolution performance. By virtues of the multilevel structure, the O-HEA(2) electrode exhibits impressive OER properties with a low overpotential of 268 mV and Tafel slope of 51.6 mV dec(-1) in 1 M KOH at 10 mA cm(-2). It also exhibits a long durability exceed 70 h at 25 mA cm(-2). This work provides a new prospect for the rational design of large-scaled and self-supported 3D HEA based electrodes for energy conversion applications.