TM LDH Meets Birnessite: A 2D-2D Hybrid Catalyst with Long-term Stability for Water Oxidation at Industrial Operating Conditions.

TM LDH Meets Birnessite: A 2D-2D Hybrid Catalyst with Long-term Stability for Water Oxidation at Industrial Operating Conditions. Angew Chem Int Ed Engl. 2021 Jan 23;: Authors: Long X, Chen Z, Ju M, Sun M, Jin L, Cai R, Wang Z, Dong L, Peng L, Huang B, Yang S Abstract Efficient noble-metal free electrocatalyst for oxygen evolution reaction (OER) is critical for large-scale hydrogen production via water splitting. Inspired by Nature's oxygen evolution cluster in photosystem II and the highly efficient artificial OER catalyst of NiFe layered double hydroxide (LDH), we designed an electrostatic 2D-2D assembly route and successfully synthesized a 2D LDH(+)-Birnessite(-) hybrid. The as-constructed LDH(+)-Binessite(-) hybrid catalyst showed advanced catalytic activity and excellent stability towards OER under a close to industrial hydrogen production condition (85 ÂșC and 6 M KOH) for more than 20 h at the current densities larger than 100 mA/cm 2 . Experimentally, we found that besides the enlarged interlayer distance, the flexible interlayer NiFe LDH(+) also modulates the electronic structure of layered MnO 2 , and creates an electric field between NiFe LDH(+) and Birnessite(-), wherein OER occurs with a greatly decreased overpotential. DFT calculations confirmed the interlayer LDH modulations of the OER process, attributable to the distinct electronic distributions and environments. Upshifting the Fe-3d orbitals in LDH promotes electron...
Source: Angewandte Chemie - Category: Chemistry Authors: Tags: Angew Chem Int Ed Engl Source Type: research