Iron-cation-coordinated cobalt-bridged-selenides nanorods for highly efficient photo/electrochemical water splitting

“…It is urgent to develop alternative non‐precious electrocatalysts to realize efficient and sustainable hydrogen production. [ 2 ] Among them, transition metal compounds (TMCs) are quite appealing and frequently investigated, including phosphides, [ 3 ] oxides, [ 4 ] hydroxides, [ 5 ] sulfides, [ 6 ] selenides, [ 7 ] and so on.…”

A General Self‐Assembly Induced Strategy for Synthesizing 2D Ultrathin Cobalt‐Based Compounds Toward Optimizing Hydrogen Evolution Catalysis

“…It is urgent to develop alternative non‐precious electrocatalysts to realize efficient and sustainable hydrogen production. [ 2 ] Among them, transition metal compounds (TMCs) are quite appealing and frequently investigated, including phosphides, [ 3 ] oxides, [ 4 ] hydroxides, [ 5 ] sulfides, [ 6 ] selenides, [ 7 ] and so on.…”

A General Self‐Assembly Induced Strategy for Synthesizing 2D Ultrathin Cobalt‐Based Compounds Toward Optimizing Hydrogen Evolution Catalysis

“…Tremendous attention and endeavours have been devoted to earth-abundant electrocatalysts including transition metal carbides/borides/nitrides/oxides/selenides/phosphides/dichalcogenides, [11][12][13][14][15][16][17] and perovskites, 18 and carbon materials 19 have been intensely investigated. Among these electrocatalysts, transition metal phosphides (TMPs) are considered as promising electrocatalysts due to their high activity in all-pH electrolytes, as well as because of the fact that the metal and phosphorus atoms on the surface of metal phosphides serve as proton and hydride acceptor centres, which improves the electronic structures of these electrocatalysts.…”

Multi-interfacial engineering of a coil-like NiS–Ni₂P/Ni hybrid to efficiently boost electrocatalytic hydrogen generation in alkaline and neutral electrolyte

“…[1][2][3][4][5][6] Over the last decade, this technology has been the target of fundamental and technological scientic research to develop new classes of nanostructured materials with unique properties and applications. [7][8][9][10][11][12] Among the interesting nanomaterials, hexagonal ferrites represent important classes of magnetic materials in diverse areas of applications such as plastic magnets, permanent magnets, recording media, microwave components, high-frequency devices, and catalysts or photocatalysts. [13][14][15][16] Since their discovery in the 1950s there has been an increasing degree of interest in the hexagonal ferrites, 17 and their synthesis and study deserve a particular interest for R&D researchers.…”

Synergistic effect of GO/SrFe₁₂O₁₉ as magnetic hybrid nanocatalyst for regioselective ring-opening of epoxides with amines under eco-friendly conditions