Surface Reconstruction of Ni-Fe Layered Double Hydroxide Inducing Chloride Ion Blocking Materials for Outstanding Overall Seawater Splitting

Generation of hydrogen fuel via electrochemical water splitting powered by sustainable energy, such as wind or solar energy, is an attractive path toward the future renewable energy landscape. However, current water electrolysis requires desalinated water resources, eventually leading to energy costs and water scarcity. The development of cost-effective electrocatalysts capable of splitting saline water feeds directly can be an evident solution. Herein, a surface reconstructed nickel-iron layered double hydroxide (NF-LDH) is reported as an exceptionally active and durable bifunctional electrocatalyst for saline water splitting without chloride corrosion. The surface reconstructed NF-LDH consists of Ni3Fe alloy phase interconnected in a 2D network in which an ultrathin (approximate to 2 nm) and low-crystalline NiFe (oxy)hydroxide phase are formed on the surface. The NiFe (oxy)hydroxide phase draws large anodic current densities, satisfying the level of practical application, while the Ni3Fe alloy phase is simultaneously responsible for the high catalytic activity for cathodic reactions and superior corrosion resistance. The surface reconstructed NF-LDH electrode can be easily fabricated in a large electrode area (up to 25 cm(2)) and can successfully produce hydrogen fuels from saline water powered by the laboratory-made low-intensity photovoltaic cell.

Automated summary

Generating hydrogen fuel through electrochemical water splitting powered by sustainable energy sources is a promising approach for future renewable energy. However, current electrolysis methods require desalinated water, leading to energy costs and water scarcity. This study introduces a cost-effective electrocatalyst, the surface reconstructed nickel-iron layered double hydroxide (NF-LDH), which can split saline water without chloride corrosion. The NF-LDH electrode exhibits exceptional activity and durability, with Ni3Fe alloy phase responsible for catalytic activity and corrosion resistance.