[1] P S SHAO, P X XIONG, D L JIANG et al. Tunable and enhanced mechanoluminescence in LiYGeO₄: Tb³⁺via Bi³⁺→Tb³⁺ energy transfer. Journal of Materials Chemistry C, 11, 2120(2023).

[2] T HU, Y GAO, B WANG et al. A new class of battery-free, mechanically powered, piezoelectric Ca₅Ga₆O₁₄: Tb³⁺ phosphors with self-recoverable luminescence. Journal of Materials Chemistry C, 10(2022).

[3] S Q LIU, Y T ZHENG, D F PENG et al. Near-infrared mechanoluminescence of Cr³⁺ doped gallate spinel and magnetoplumbite smart materials. Advanced Functional Materials, 33(2023).

[4] A QASEM, P P XIONG, Z J MA et al. Recent advances in mechanoluminescence of doped zinc sulfides. Laser & Photonics Reviews, 15(2021).

[5] P X XIONG, B L HUANG, D F PENG et al. Self-recoverable mechanically induced instant luminescence from Cr³⁺-doped LiGa₅O₈. Advanced Functional Materials, 31(2021).

[6] F T FREUND. Rocks that crackle and sparkle and glow: strange pre-earthquake phenomena. Journal of Scientific Exploration, 17(2003).

[7] H SONG, S TIMILSINA, J Y JUNG et al. Improving the sensitivity of the mechanoluminescence composite through functionalization for structural health monitoring. ACS Applied Materials & Interfaces, 14(2022).

[8] N TERASAKI, C N XU. Historical-log recording system for crack opening and growth based on mechanoluminescent flexible sensor. IEEE Sensors Journal, 13(2013).

[9] Y JIA, M YEI, W Y JIA. Stress-induced mechanoluminescence in SrAl₂O₄: Eu²⁺, Dy³⁺. Optical Materials, 28(2006).

[10] S M JEONG, S SONG, K I JOO et al. Bright, wind-driven white mechanoluminescence from zinc sulphide microparticles embedded in a polydimethylsiloxane elastomer. Energy & Environmental Science, 7(2014).

[11] Y D SONG, J Q XIAO, L ZHAO et al. Multi-mode mechanoluminescence of fluoride glass ceramics from rigid to flexible media toward multi-scene mechanical sensors. Journal of Materials Chemistry A, 12(2024).

[12] B P CHANDRA, A S RATHORE. Classification of mechanoluminescence. Crystal Research and Technology, 30(1995).

[13] J C G BÜNZLI, K L WONG. Lanthanide mechanoluminescence. Journal of Rare Earths, 36(2018).

[14] J L CAO, S S DING, Y P ZHOU et al. Unveiling the potential of sunlight-driven multifunctional blue long persistent luminescent materials via cutting-edge trap modulation strategies. Advanced Optical Materials, 12, 2302011(2024).

[15] S WU, P X XIONG, D L JIANG et al. Single Tb³⁺ ion doped ratiometric mechanoluminescence for tunable stress visualization. Chemical Engineering Journal, 469, 143961(2023).

[16] Y XIAO, P X XIONG, S ZHANG et al. Deep-red to NIR mechanoluminescence in centrosymmetric perovskite MgGeO₃: Mn²⁺ for potential dynamic signature anti-counterfeiting. Chemical Engineering Journal, 453, 139671(2023).

[17] Y XIAO, P X XIONG, Y K LE et al. Defect-management-induced multi-stimulus-responsive mechanoluminescence in Mn²⁺ doped gallate compound. Nano Energy, 120, 109086(2024).

[18] Y Q BAI, X P GUO, B R TIAN et al. Self-charging persistent mechanoluminescence with mechanics storage and visualization activities. Advanced Science, 9(2022).

[19] P S SHAO, P X XIONG, Y XIAO et al. Self-recoverable NIR mechanoluminescence from Cr³⁺ doped perovskite type aluminate. Advanced Powder Materials, 3(2024).

[20] X Y QIU, J Z LIU, B ZHOU et al. Bioinspired bimodal mechanosensors with real-time, visualized information display for intelligent control. Advanced Functional Materials, 33(2023).

[21] S H HU, Z W LONG, Y G WEN et al. An orange-emitting phosphor BaSrGa₄O₈: Bi³⁺, K⁺ with unique one-dimensional chain structure for high index color WLEDs. Journal of the American Ceramic Society, 103(2020).

[22] S S DING, P H CHEN, H J GUO et al. Crystal structure and optical performance analysis of a new type of persistent luminescence material with multi-functional application prospects. Journal of Energy Chemistry, 69, 150(2022).