Jump to main content
Jump to site search

Issue 41, 2017
Previous Article Next Article

How sulfidation of ZnO powders enhances visible fluorescence

Author affiliations


The mechanism for producing efficient white light phosphors from sulfidated zinc oxide (ZnO) powders is elucidated. ZnO powders prepared by vacuum annealing produce powders of oxygen-deficient ZnO:Zn, while ZnO powders annealed in a sulfur atmosphere produce a doped ZnO core with a radially-increasing sulfur concentration gradient capped by a shell of zinc sulfide (ZnS) domains, ZnO:S/ZnS. As compared to ZnO:Zn powders, the intensity and quantum efficiency of the broad, green-tinted white defect fluorescence more than doubled for the ZnO:S/ZnS powders. This fluorescence is mediated by certain neutral donor-bound excitons (DBEs), and it is found that the DBE lifetime and the rate of energy transfer to the defect emission band increases for the ZnO:S/ZnS powders. These DBEs are destroyed by photoexcited free holes, and the hypothesis that they are removed by the type-II band alignment of the ZnS cap with the ZnO:S core is confirmed when ZnO:Zn and ZnO:S/ZnS powders under vacuum are dosed with the hole scavenger methanol: defect emission increases as the free hole concentration decreases. The highest ZnO:S/ZnS quantum efficiency occurs when excited through an impurity band, also produced by sulfur doping, whose energy coincides with the light emitting diodes used for commercial solid state lighting.

Graphical abstract: How sulfidation of ZnO powders enhances visible fluorescence

Back to tab navigation

Supplementary files

Publication details

The article was received on 04 Sep 2017, accepted on 28 Sep 2017 and first published on 29 Sep 2017

Article type: Paper
DOI: 10.1039/C7TC04047D
Citation: J. Mater. Chem. C, 2017,5, 10770-10776

  •   Request permissions

    How sulfidation of ZnO powders enhances visible fluorescence

    J. G. Simmons, M. E. Reish, J. V. Foreman, J. Liu and H. O. Everitt, J. Mater. Chem. C, 2017, 5, 10770
    DOI: 10.1039/C7TC04047D

Search articles by author