Qiulin Nie

Self-assembly of dandelion-like NiCo2O4 hierarchical microspheres for non-enzymatic glucose sensor

ABSTRACT The dandelion-like NiCo2O4 hierarchical microspheres were successfully prepared and used as the nonenzymatic glucose sensing materials. The characterization showed that the as prepared hierarchical dandelion-like NiCo2O4 microspheres are composed of closely connected outstretched nanowires with the average diameter about 50 nm and length about 1–1.5 μm with the substructured nanowires made up of nanoparticles with the diameters less than 10 nm. The dandelion-like NiCo2O4 hierarchical microspheres exhibited superior electrochemical activity towards oxidation of glucose, which is much higher than that of pure NiO microspheres. The amperometric responses are linear with glucose in the concentration range of 10–10480 μM a sensitivity of 430.86 μA cm−2 mM−1. Moreover, the interference from the commonly interfering species such as L-valine, urea, L-proline, NaCl and L-lysine can be effectively avoided. The good electrochemical performance of materials may be due to its complex chemical compositions, hierarchical structure and the synergetic effect of both individual components. The high sensitivity, wide glucose detection range and good selectivity indicated that the newly developed sensor based on the dandelion-like NiCo2O4 hierarchical microspheres is a promising sensor for practical application.

Synergistically enhanced visible light photocatalytic activity by surface plasmon and facet-dependent oxygen vacancy on Ag/BiOCl

Abstract The Ag/BiOCl (0 0 1) nanosheets were prepared by an UV-induced simultaneous generation of Ag nanoparticles and oxygen vacancy on the (0 0 1) facet of BiOCl nanosheets, and the (0 0 1) facet-dominant BiOCl was synthesised through a milder reaction condition at room temperature. Characteristics and properties of the products were investigated using XRD, DRS, XPS, SEM and TEM. The results showed that the BiOCl nanosheets have the tetragonal phase structures and sheet-like morphologies with thickness about 50 nm and width ranging from 200 to 400 nm. The Ag nanoparticles and oxygen vacancy were successfully formed on the (0 0 1) facet of BiOCl nanosheets. The as-prepared Ag/BiOCl nanosheets showed greatly enhanced visible light-induced photocatalytic activity in methyl orange degradation. The increased visible photocatalytic performance of Ag/BiOCl nanosheets was analytically due to the synergetic effect of surface plasmon and facet-dependent oxygen vacancy on the (0 0 1) facet of BiOCl.