of the global, a series of European countries have proposed to directly develop seawater electrolysis for hydrogen production, which can reduce the strong dependence on resource-constrained freshwater, and avoid energy intensive desalination. [4] However, the hydrogen evolution reaction (HER) at the cathode and oxygen evolution reaction (OER) at the anode during water electrolysis are inhibited by sluggish kinetics, and efficient electrocatalysts are required to overcome the reaction energy barrier. [5] The noble metals Pt and Ir/Ru oxides are considered benchmark catalysts for the HER and OER. However, their high cost, scarcity, and poor stability limit their large-scale applications. [6] Therefore, it is an urgent to develop efficient, stable, and economically bifunctional electrocatalysts.Porous organic frameworks (POFs), covalent organic frameworks (COFs), and metal-organic frameworks (MOFs) have been widely employed as raw materials in water electrolysis. MOFs are novel porous materials with regular and adjustable pores, high porosity, and large specific surface areas (SSAs). Thus, MOFs provide advantages, such as a strong adsorption capacity, easy modification, and abundant unsaturated metal active sites. [7] However, MOF-based catalytic materials tend to accumulate in the actual catalysis process owing to their rigorous preparation conditions requiring high pressure and temperature, leading to unstable coordination bonds between the organic ligands and central metal atoms as well as unsatisfactory stability. Furthermore, the difficulty of large numbers of overlapping highly electronegative oxygen atoms with d orbitals from other metal ions over a large area also leads to a low charge transfer efficiency of MOF-based catalysts. [8] To address this, Lin et al. successfully prepared a Pt@MOF electrode at 100 °C for 72 h, which produced a large amount of hydrogen and durable catalysis water electrolysis for 6 h. [9] Chen et al. synthesized N-doped bimetallic FeCo-MOF combined with graphene through carbonization at 800 °C, resulting in an overpotential of only 262 mV at 10 mA cm −2 during the HER. [10] Kim et al. obtained an Fe-doped MOF CoV@CoO bifunctional catalyst through a solution growth process at 80 °C under vigorous stirring, followed by in situ growth of the MOF on the surface and a final calcination step in a muffle furnace Mild construction of highly efficient and durable practical electrodes for overall water splitting (OWS) at industrial-grade current density is currently a significant challenge. Herein, metal-organic framework (MOF) materials are grown in situ on the surface of carbon cloth (CC) at 25 °C, and quickly "interspersed" by cobalt-boron (Co-B) via electroless plating for 30 min to obtain a highly efficient and stable CoB@MOF@CC self-supporting electrode. Owing to the large specific surface area, abundant active sites, and porous structure, the MOF-based CC modified by bamboo leaf-like ultrathin CoB has remarkable electrochemical catalysis efficiency. The CoB@MOF@CC electrode exhibits...
