CrossRef 13. Minico S, Scire S, Crisafulli C, Galvagno S: Influence of catalyst pretreatments on volatile organic compounds oxidation over gold/iron oxide. Appl Catal B-Environ 2001, 34:277–285.CrossRef 14. Abad A, Concepcion P, Corma A, Garcia H: A collaborative effect between gold and a support induces the selective oxidation
of alcohols. Angew Chem-Int Edit 2005, 44:4066–4069.CrossRef 15. Abad A, Almela C, Corma A, Garcia H: Efficient selleck chemicals llc chemoselective alcohol oxidation using https://www.selleckchem.com/TGF-beta.html oxygen as oxidant. Superior performance of gold over palladium catalysts. Tetrahedron 2006, 62:6666–6672.CrossRef 16. Enache DI, Edwards JK, Landon P, Solsona-Espriu B, Carley AF, Herzing AA, Watanabe M, Kiely CJ, Knight DW, Hutching GJ: Solvent-free oxidation of primary alcohols to aldehydes using Au-Pd/TiO 2 catalysts. Science 2006, 311:362–365.CrossRef 17. Enache DI, Knight DW, Hutchings GJ: Solvent-free oxidation of primary alcohols to aldehydes using supported gold catalysts. Catal Lett 2005, 103:43–52.CrossRef 18. Haider P, Baiker A: Gold supported on Cu-Mg-Al-mixed oxides: strong enhancement of activity in aerobic alcohol oxidation by concerted effect of copper and magnesium. J Catal 2007, 248:175–187.CrossRef Competing interests The authors declare that they have no competing interests. Authors’ contributions XBF carried out the synthesis of the materials and drafted the manuscript. ZD, XZ,
and WLW participated in the characterization of the materials. The whole project was check details under the direction of YJX. JXL and ZKX participated in the testing of the catalytic activity of the materials. All selleck screening library authors read and approved the final manuscript.”
“As one of the most important materials, ZnO has been extensively applied in numerous purposes which include optics, energy [1, 2], piezo-phototronics [3–6], Schottky contact nanosensors [7–9], biomedical sciences [10, 11], and spintronics [12]. Due to diverse and abundant nanostructures and a great potential in nanotechnology, a great number of novel ZnO nanodevices such as piezoelectric power generators
[13–16], field-effect transistors (FET) [17, 18], ultraviolet photodetectors [19], Schottky diodes [6, 20–22], switches [21], and flexible piezotronic strain sensors [23] are gradually under research. Those devices, moreover, are expected to operate in various environments; therefore, maintaining their great performance and stability for an extended period of time is required. Due to this reason, nanostructures of ZnO in different atmospheres have become an interesting topic to study. According to several research articles, amorphous ZnCO3 thin films and nanowires could be formed due to the defacing of ZnO nanostructures by moisture and the small amount of CO2 in the atmosphere [24, 25]. In this work, we would figure out the mechanisms of the spontaneous reaction and prove the efficacy of c-ZnO NWs surface passivation that would suppress the spontaneous reaction.