Constructing multifunctional 'Nanoplatelet-on-Nanoarray' electrocatalyst with unprecedented activity towards novel selective organic oxidation reactions to boost hydrogen production

Replacing oxygen evolution reaction with thermodynamically more favorable organic oxidation reactions is considered as attractive approach to enhance the energy conversion efficiency in electrochemical water splitting. Herein, 'Nanoplatelet-on-Nanoarray' NiCo hydroxide-based electrocatalysts (t-NiCo-MOF) fabricated from the facile transformation of bimetallic metal-organic framework nanoarrays is reported to exhibit rich surface active sites and unprecedented activity towards the oxidation of organic molecules including 5-hydroxymethylfurfural, urea, methanol and glycerol. Benefitting from the synergy between Ni/Co and unique nanostructure which facilitates the charge and mass transfer, the optimal electrode exhibits current densities of 600 similar to 730 mA/cm(2) at 1.4 V vs RHE and the Tafel slopes are in the range of 35 similar to 58 mV/dec depending on the oxidized species. Value-added chemicals such as 2,5-furandicarboxylic acid and formate are produced from HMF and methanol/glycerol (main constituents of 'bio-glycerol') with high FE and superior stability, demonstrating its promises in high-throughput electrochemical biomass upgrading.