The NSs are mostly rectangular in shape with sides of 1 to 5 μm and a minimum thickness of 20 nm, with a structure typical of lamellar growth. Partial thermal decomposition into ZnO occurs after annealing in air at 200°C and is complete after 400°C, producing ZnO nanocrystalline NSs. Annealing at

higher temperatures results in an increase of the nanoparticle size within the NSs and sintering was observed after 600°C. The NSs keep their shape even after annealing at 1,000°C. PL data selleckchem show a significant deep level emission comprising several distinct transitions. The exciton to deep level intensity ratio was highest at 400°C and decreased at higher temperatures and with longer annealing times at 400°C. The shape of the deep level S63845 purchase band was also altered by the annealing temperature. ZnO NSs produced by annealing at 400°C were used to fabricate DSCs and resistive gas sensors. The DSCs showed an overall efficiency of 1.3% whilst the response of the www.selleckchem.com/products/cbl0137-cbl-0137.html sensors at 350°C was 1.65

and 1.13 at 200 and 12.5 ppm, respectively. These results highlight the potential of the material for device applications. Acknowledgements This work was supported by the Royal Society (TGGM), the Welsh European Funding Office (RAB, MWP, DRJ, CJN), the Engineering and Physical Science Research Council (DTJB, AT). KEM and RM gratefully acknowledge support from the National Science Foundation CBET-0933719. References 1. Wang ZL: Zinc oxide nanostructures:

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