Porous microtubes of nickel-cobalt double oxides as non-enzymatic hydrogen peroxide sensors

Abstract

Non-enzymatic electrochemical sensors for the determination of hydrogen peroxide (H2O2) have attracted more and more concerns. A series of nickel and cobalt double oxides (NixCoy-DO) with the different ratios of Ni/Co have been prepared by a polyol-mediated solvothermal method for H2O2 detection. The obtained products exhibit honeycomb-like open porous microtubes constituted with the low-dimensional nanostructured NixCoy-DO blocks after the calcination treatment. Compared with nickel oxides, the introduced Co ions in NixCoy-DO can induce the production of surficial oxygen vacancies, and further enhance the electrode surface activity. In particular, the NiCo-DO sample (with an atomic ratio of Ni/Co = 4:3) shows the richest surficial oxygen vacancies and presents the highest H2O2 detection activity among all the as-prepared samples, demonstrating an excellent sensitivity of 698.60 μA L mmol−1 cm-2 (0 ∼ 0.4 mmol/L), low detection limit (0.28 μmol/L, S/N = 3), as well as long stability, high selectivity and good reproducibility. This work lends a new impetus to the potential application of double metal oxides for the next generation of non-enzymatic sensors.