Origin of mechanoluminescence from Mn-activated ZnAl 2 O 4 : Triboelectricity-induced electroluminescence

Date

2004

Authors

Matsui, Hiroaki
Xu, Chao-Nan
Liu, Yun
Tateyama, Hiroshi

Journal Title

Journal ISSN

Volume Title

Publisher

American Physical Society

Abstract

Luminescence induced by friction, mechanoluminescence (ML) has been observed for ZnAl2O4: Mn2+ (ZAO:Mn) fabricated by systematically controlling the reducing temperature. The reducing treatment produced lattice defects under a reducing atmosphere. Those defects were associated with Zn and O vacancies through evaporation of ZnO in ZnAl 2O4, which was trapped with a large amount of carrier in the spinel. Results of dependence of ML intensity and integrated intensity for thermoluminescence on the reducing temperature showed that the trapped carrier plays an important role in producing the ML for ZAO:Mn. In addition, the ML for ZAO:Mn was strongly dependent upon the friction rod material; it was closely related to the surface voltage generated in the vicinity of the frictional surface. These results suggest that the ML for ZAO:Mn was caused by the effect of triboelectrification, but not piezoelectricity because ZnAl2O 4 has a centrosymmetric structure (Fd3m). Therefore, the carrier that is trapped in the spinel can be excited by the local electric field derived from friction between the two dissimilar materials, where the excited carrier is accelerated toward the luminescent center of the Mn2+ ions. Consequently, the Mn2+ ions are excited and release an emission band on the transition from 4T1 to 6A1. Evidence for these physical processes was corroborated from the finding that reduced ZAO:Mn showed highly efficient electroluminescence (EL). Therefore, it is inferred that the ML for ZAO:Mn is caused by triboelectricity-induced EL.

Description

Keywords

Keywords: aluminum derivative; manganese; metal oxide; zinc derivative; article; crystal structure; electric field; electric potential; electricity; evaporation; friction; luminescence; mechanoluminescence; piezoelectricity; reduction; surface property; temperature

Citation

Source

Physical Review B: Condensed Matter and Materials

Type

Journal article

Book Title

Entity type

Access Statement

License Rights

Restricted until

2037-12-31