[1] [1] FENG A, SMET P F. A review of mechanoluminescence in inorganic solids: compounds, mechanisms, models and applications[J]. Materials, 2018, 484(11): 1-56.

[2] [2] PENG Dengfeng, CHEN Bing, WANG Feng. Recent advances in doped mechanoluminescent phosphors[J]. ChemPlusChem, 2015, 80: 1209-1215.

[3] [3] XIONG Puxian, PENG Mingying, YANG Zhongmin. Near infrared mechanoluminescence crystals: A review[J]. iScience, 2021, 101944(24): 1-14.

[4] [4] MA Zhidong, ZHOU Jinyu, ZHANG Jiachi, et al. Mechanics-induced triple-mode anticounterfeiting and moving tactile sensing by simultaneously utilizing instantaneous and persistent mechanoluminescence[J]. Mater Horiz, 2019, 6: 2003.2008.

[5] [5] ZHUANG Yixi, XIE Rongjun. Mechanoluminescence rebrightening the prospects of stress sensing: A review[J]. Adv Mater, 2021, 2005925(33): 1.33.

[6] [6] ZHANG Juncheng, WANG Xusheng, MARRIOTTC G, et al. Trap-controlled mechanoluminescent materials[J]. Progr Mater Sci, 2019, 103: 678.742.

[7] [7] ZHANG Juncheng, GAO Nan, LI Lei, et al. Discovering and dissecting mechanically excited luminescence of Mn2+ activators via matrix microstructure evolution[J]. Adv Funct Mater, 2021, 2100221(31): 1-9.

[8] [8] WANG Chunfeng, PENG Dengfeng, et al. Mechanoluminescence materials for advanced artificial skin[J]. Sci Bull, 2020, 65: 1147-1149.

[9] [9] ZHANG Juncheng, XUE Xuyan, YI Fei, et al. Ultra-long-delay sustainable and short-term-friction stable mechanoluminescence in Mn2+-activated NaCa2GeO4F with centrosymmetric structure[J]. Chem Eng J, 2021, 126798(406): 1-9.

[10] [10] YANG Yunling, YANG Xuechun, YUAN Jiayong, et al. Time-Resolved bright red to cyan color tunable mechanoluminescence from CaZnOS:Bi3+, Mn2+ for anti-counterfeiting device and stress sensor[J]. Adv Opt Mater, 2021, 2100668(9): 1-12.

[11] [11] FAN Yuting, YANG Yunling, Li Ting, et al. Enhanced mechanically induced red-light emitting novel mechanoluminescence materials for ultrasonic visualization and monitoring applications[J]. J Mater Chem C, 2021, 9: 5868-5875.

[12] [12] XIONG Puxian, HUANG Bolong, PENG Dengfeng, et al. Self-recoverable mechanically induced instant luminescence from Cr3+-doped LiGa5O8[J]. Adv Funct Mater, 2021, 2010685(31): 1-11.

[13] [13] XU Chaonan, WATANABE T, AKIYAMA M, et al. Direct view of stress distribution in solid by mechanoluminescence[J]. Appl Phys Lett, 1999, 74: 2414.2416.

[14] [14] XU Chaonan, WATANABE T, AKIYAMA M, et al. Artificial skin to sense mechanical stress by visible light emission[J]. Appl Phys Lett, 1999, 74: 1236-1238.

[16] [16] KAMIMURA S, YAMADA H, XU C. Strong reddish-orange light emission from stress-activated Srn+1SnnO3n+1 (n=1, 2, ∞) with perovskite-related structures[J]. Appl Phys Lett, 2012, 091113(101): 1-4.

[17] [17] TU Dong, XU Chaonan, KAMIMURA S, et al. Ferroelectric Sr3Sn2O7:Nd3+: A new multipiezo material with ultrasensitive and sustainable near-infrared piezoluminescence[J]. Adv Mater, 2020, 1908083(32): 1-9.

[18] [18] TU Dong, HAMABE R, XU Chaonan. Sustainable mechanoluminescence by designing a novel pinning trap in crystals[J]. J Phys Chem C, 2018, 122(41): 23307-23311.

[19] [19] LI Jun, XU Chaonan, TU Dong, et al. Tailoring bandgap and trap distribution via Si or Ge substitution for Sn to improve mechanoluminescence in Sr3Sn2O7:Sm3+ layered perovskite oxide[J]. Acta Mater, 2018, 145: 462-469.

[20] [20] LEI Bingfu, MAN Shiqing, LIU Yingliang, et al. Luminescence properties of Sm3+-doped Sr3Sn2O7 phosphor[J]. Mater Chem Phys, 2010, 124: 912-915.