Issue 9, 2023

Cation-defect-induced self-reduction towards efficient mechanoluminescence in Mn2+-activated perovskites

Abstract

Mechanoluminescent (ML) materials have shown promising prospects for various applications, e.g. in stress sensing, information anti-counterfeiting and bio stress imaging fields. However, the development of trap-controlled ML materials is still limited, because the trap formation mechanism is not always clear. Here, inspired by a defect-induced Mn4+ → Mn2+ self-reduction process in suitable host crystal structures, a cation vacancy model is creatively proposed to determine the potential trap-controlled ML mechanism. Combined with the theoretical prediction and experimental results, both the self-reduction process and ML mechanism are clarified in detail, where the contribution of Image ID:d3mh00409k-t2.gif and Image ID:d3mh00409k-t3.gif defects dominates the ML luminescent process. Electrons/holes are mainly captured by the anionic/cationic defects, followed by the combination of electrons and holes to transfer energy to the Mn2+ 3d states under mechanical stimuli. Based on the multi-mode luminescent features excited by X-ray, 980 nm laser and 254 nm UV lamp, together with the excellent persistent luminescence and ML, a potential application in advanced anti-counterfeiting is demonstrated. These results will deepen the understanding of the defect-controlled ML mechanism, and inspire more defect-engineering strategies to develop more high-performance ML phosphors for practical application.

Graphical abstract: Cation-defect-induced self-reduction towards efficient mechanoluminescence in Mn2+-activated perovskites

Supplementary files

Article information

Article type
Communication
Submitted
17 Mar 2023
Accepted
15 May 2023
First published
16 May 2023

Mater. Horiz., 2023,10, 3476-3487

Cation-defect-induced self-reduction towards efficient mechanoluminescence in Mn2+-activated perovskites

Y. Xiao, P. Xiong, S. Zhang, Y. Sun, N. Yan, Z. Wang, Q. Chen, P. Shao, M. G. Brik, S. Ye, D. Chen and Z. Yang, Mater. Horiz., 2023, 10, 3476 DOI: 10.1039/D3MH00409K

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