Vacancy and doping engineering of Ni-based charge-buffer electrode for highly-efficient membrane-free and decoupled hydrogen/oxygen evolution

The realization of the membrane-free two-step water electrolysis is particularly important yet challenging for the low-cost and large-scale supply of hydrogen energy. In this effort, Co-doped Ni(OH)₂ nanosheets were successfully anchored onto the nickel foam (NF) substrate through the in-situ growth of metal-organic frame material and the subsequent alkali-etching technique. Using the well-regulated Co-doping Ni(OH)₂@NF electrodes as a charge mediator, electrochemical hydrogen evolution reaction (HER) and oxygen evolution reaction (OER) were decoupled on time scales, thus affording a membrane-free two-step route for H₂ and O₂ productions. In this architecture, the first HER process on the cathode could be maintained for 1300 s at a current of 100 mA, while the corresponding Ni(OH)₂ charge mediator was simultaneously oxidized to NiOOH, with a decent cell voltage of 1.542 V. The subsequent OER process involved a reduction/regeneration of Ni(OH)₂ (from NiOOH to Ni(OH)₂) and an anodic O₂-production, with an operating voltage of 0.291 V. Moreover, the Ni-Zn battery assembled through the combination of NiOOH and Zn sheet could replace the second step of OER to achieve the coupling of continuous H₂-production and battery discharge, thus also providing a new way for hydrogen production without an external power supply. Experiment and theoretical calculations have shown that the cobalt-doping not only improved the conductivity of the charge-buffer electrode, but also shifted its redox potential cathodically and boosted the adsorption affinity of the buffer medium to OH^- ions, both contributing to promoted HER and OER activity. Therefore, this decoupled water electrolysis device affords a promising pathway to support the efficient conversion of renewables to hydrogen.

Oxygen vacancy on Nb2O5 enhanced the performance of H2O2 electrosynthesis from O2 reduction

A serial oxygen vacancy (OV) on Nb2O5 is synthesised by H2 calcination, the H-300 exhibited high selectivity and activity of H2O2 (93.4%, 562.5 mmol gcat-1). The volcano relationship is identified...

Ferromagnetic behavior of non-stoichiometric ZnS microspheres with a nanoplate-netted surface

(A) SEM images of undoped ZnS microspheres; (B) M–H magnetic hysteresis loops for the atomic ratio of Zn to S equal to 0.966 (black line) and 1.32 (blue line).