2024年

1.Li L, Li P, Lv X, et al. Ultraviolet-C mechanoluminescence from NaYF4: Pr3+[J]. Applied Physics Letters, 2024, 124(10).

2.Zhang F, Golovynskyi S, Datsenko O I, et al. Photoluminescence thermometry using broadband multi-peak detection in Eu2+/Eu3+-codoped oxygen-rich AlN film[J]. Optical Materials, 2024, 149: 115095.

3.Shao J, Li X, Liu M, et al. A time-dependent luminescent phosphor of Na2Ba2Si2O7: Eu for multi-level encryption and dynamic information display[J]. Journal of Advanced Ceramics, 2024.

4.Cai C, Li L, Li H, et al. All‐Lanthanide Mechanoluminescence from Transparent Ln‐doped MgF2@ Elastomer for Flexible and Stretchable Lighting and Stress Sensing[J]. Advanced Materials Technologies, 2024: 2301855.

5.Zhang Q, Li P, Xu Z, et al. Unlocking The Inherent Luminescence of Eu2+/Eu3+ by Light‐Induced Oxidation for Invisible Optical Storage[J]. Laser & Photonics Reviews, 2024: 2300925.

6.Liu H, Zheng Y, Liu S, et al. Realizing Red Mechanoluminescence of ZnS: Mn2+ Through Ferromagnetic Coupling[J]. Advanced Functional Materials, 2024: 2314422.

7.Song Z, Yu R, Zhang X, et al. SATac: A Thermoluminescence Enabled Tactile Sensor for Concurrent Perception of Temperature, Pressure, and Shear[J]. arXiv preprint arXiv:2402.00585, 2024.

8.He X, Zheng Y, Luo Z, et al. Bright Circularly Polarized Mechanoluminescence from 0D Hybrid Manganese Halides[J]. Advanced Materials, 2024: 2309906.

9.Wang Y, Fan J, Su H, et al. The determining role of stacking fault in the mechanoluminescence properties of ZnS: Mn thin films[J]. Applied Surface Science, 2024: 159583.

10.Yang H, Wei Y, Ju H, et al. Microstrain-Stimulated Elastico-Mechanoluminescence with Dual-Mode Stress Sensing[J]. Advanced Materials (Deerfield Beach, Fla.), 2024: e2401296-e2401296.

11.Golovynskyi S, Kanwal Z, Babichuk I S, et al. Color manipulation of mechanoluminescence and photoluminescence from CaZnOS: ZnS: Mn2+ heterocompound controlled by ion doping concentration[J]. Journal of Alloys and Compounds, 2024: 174437.

12.Pan X, Zhuang Y, He W, et al. Quantifying the interfacial triboelectricity in inorganic-organic composite mechanoluminescent materials[J]. Nature Communications, 2024, 15(1): 2673.

13.Li X, Liu M, Shao J, et al. High‐Capacity Photochromic Rotary Encoder for Information Encryption and Storage[J]. Advanced Functional Materials, 2024: 2402603.

14.Hou T, Li W, Wang H, et al. An ultra thin, bright, and sensitive interactive tactile display based on organic mechanoluminescence for dual‐mode handwriting identification[J]. InfoMat, 2024: 12523.

15.Du Y, Jin Z, Li Z, et al. Tuning the 5d State of Pr3+ in Oxyhalides for Efficient Deep Ultraviolet Upconversion[J]. Advanced Optical Materials, 2400971.

16.Zhu W, Chen B, Peng D. The stretchable perovskite-based alternating current electroluminescence for human-device interaction[J]. Science bulletin, 2024: S2095-9273 (24) 00508-5.

17.Golovynskyi S, Zhang F, Luo J, et al. Sm3+-doped oxygen-rich AlN film: Probing luminescence thermometry and evidencing energy transfer via Sm-O pairs[J]. Journal of Alloys and Compounds, 2024: 177365.

18.Li H, Yang Y, Li P, et al. Force‐Induced Ultraviolet C Luminescence of Pr3+‐Doped Sr2P2O7 for X‐Ray Dosimetry[J]. Advanced Materials, 2024: 2411804.

19.Shao J, Li X, Liu M, et al. Non‐volatile and Secure Optical Storage Medium with Multilevel Information Encryption[J]. Advanced Science, 2024: 2408287.

20.Zheng T, Luo J, Peng D, et al. Persistent Photoluminescence and Mechanoluminescence of a Highly Sensitive Pressure and Temperature Gauge in Combination with a 3D‐Printable Optical Coding Platform[J]. Advanced Science, 2024: 2408686.

21.Huang Z, Li X, Liang T, et al. Smart mechanoluminescent phosphors: A review of zinc sulfide‐based materials for advanced mechano‐optical applications[J]. Responsive Materials, 2024, 2(3): e20240019.

2023年

1.Ren B, Chen B, Zhang X, et al. Mechanoluminescent optical fiber sensors for human-computer interaction[J]. Science Bulletin, 2023: S2095-9273 (23) 00134.

2.Chen B, Peng D, Lu P, et al. Modeling and validating mechanoluminescence-based sensing mechanism with low loading rate[J]. Materials & Design, 2023: 111588.

3.Li X, Wang C, Zheng Y, et al. Smart Semiconductor-Heterojunctions Mechanoluminescence for Printable and Wearable Sports Light Sources[J]. Materials & Design, 2023: 111589.

4.Liu S, Zheng Y, Peng D, et al. Near‐Infrared Mechanoluminescence of Cr3+ Doped Gallate Spinel and Magnetoplumbite Smart Materials[J]. Advanced Functional Materials, 2023, 33(3): 2209275.

5.Huang Z, Chen B, Ren B, et al. Smart Mechanoluminescent Phosphors: A Review of Strontium‐Aluminate‐Based Materials, Properties, and Their Advanced Application Technologies[J]. Advanced Science, 2023, 10(3): 220492

6.Li L, Cai C, Lv X, et al. Stress‐Triggered Mechanoluminescence in ZnO‐Based Heterojunction for Flexible and Stretchable Mechano‐Optics[J]. Advanced Functional Materials, 2023: 2301372.

7.Wang Z, Wang B, Zeng X, et al. Tuning Oxygen Vacancy in CaZnOS through Cation Substitution for Substantially Enhanced Multimode Luminescence of Mn2+ and Tb3+[J]. Advanced Optical Materials, 2300623.

8.Li L, Ning J, Cai C, et al. Mechanically excited thermometry in erbium ions[J]. Science China Materials, 2023, 66(4): 1615-1622.

9.Zhang X, Li X, Ren B, et al. Driving dislocation motion in ZnS single-crystalline semiconductor for extraordinary mechano-electro-optical properties[J]. Science Bulletin, 2023.

10.Lei K C, Sou K W, Chan W S, et al. WSTac: Interactive Surface Perception based on Whisker-Inspired and Self-Illuminated Vision-Based Tactile Sensor[J]. arXiv preprint arXiv:2308.13241, 2023.

11.Zhu M, Luo J, Liang T, et al. Novel Red Mechanoluminescence in Mn‐Doped ZnGa2S4 Crystal Phosphors via a Molten Salt Shielding Method[J]. Laser & Photonics Reviews, 2300517.

12.Zhou H, Wang X, He Y, et al. Distributed Strain Sensor Based on Self‐Powered, Stretchable Mechanoluminescent Optical Fiber[J]. Advanced Intelligent Systems, 2023: 2300113.

13.Chen C, Lin Z, Huang H, et al. Revealing the Intrinsic Decay of Mechanoluminescence for Achieving Ultrafast‐Response Stress Sensing[J]. Advanced Functional Materials, 2023: 2304917.

14.Wang X, Gao D, Su F, et al. Photopolymerization 3D printing of luminescent ceramics[J]. Additive Manufacturing, 2023, 73: 103695.

15.Zheng T, Runowski M, Martín I R, et al. Mechanoluminescence and Photoluminescence Heterojunction for Superior Multimode Sensing Platform of Friction, Force, Pressure, and Temperature in Fibers and 3D‐Printed Polymers[J]. Advanced Materials, 2023: 2304140.

16.Li P, Li L, Li T, et al. Mechanically induced photons from ultraviolet-C to near-infrared in Tm 3+-doped MgF 2[J]. Optics Express, 2023, 31(14): 22396-22404.

17.Xu X, Cao J, Peng D, et al. A tailor-made double-tapered fibre array enables the state-of-the-art scintillators[J]. Science bulletin, 2023: S2095-9273 (23) 00374-2.

18.Wang Z, Li Z, Wang C, et al. Mechanoluminescent Materials Enable Mechanochemically Controlled Atom Transfer Radical Polymerization and Polymer Mechanotransduction[J]. Research, 2016.

19.Yu Y, Xu H, Song E, et al. Electroluminescence, Mechanoluminescence, and Triboelectric from Superior Multimode Systems Based on Flexible Hydrogels for Human Motion Sensing[J]. Advanced Materials Technologies, 2023: 2301628.

20.Yang Q, Yu M Q, Su Z A, et al. Two Organic–Inorganic Manganese (II) Halide Hybrids Showing Compelling Photo-and Mechanoluminescence as well as Rewritable Anticounterfeiting Printing[J]. Inorganic Chemistry, 2023, 62(14): 5791-5798.

21.Zefeng Huang, Jiangcheng Luo, Biyun Ren, Xianhui Zhang, Xu Li, Yuandian Zheng, Mingju Zhu, Tianlong Liang, Qi’an Zhang, Ziyi Fang, Bing Chen, Yu Fu, Dengfeng Peng, Mechanoluminescence and afterglow modulation of Zr and Mg doped strontium aluminate,  Chinese Science Bulletin, 2023 ,68: 4716-4725.

2022年

1.Li L, Ning J, Cai C, et al. Mechanically excited thermometry in erbium ions[J]. Science China Materials, 2022: 1-8.

2.Cai C, Li L, Li P, et al. Mechanoluminescence ratiometric thermometry via MgF 2: Tb 3+[J]. Optics Letters, 2022, 47(23): 6293-6296.

3.Huang Z, Chen B, Qu S, et al. Tuning mechanoluminescent long-afterglow composites toward mechanical energy lighting[J]. Journal of Materials Science, 2022: 1-14.

4.Liu Y, Al-Salihi M, Guo Y, et al. Halogen-doped phosphorescent carbon dots for grayscale patterning[J]. Light: Science & Applications, 2022, 11(1): 163.

5.Lin F, Li X, Chen C, et al. Modeling Polyhedron Distortion for Mechanoluminescence in Mixed-Anion Compounds RE2O2S: Ln3+[J]. Chemistry of Materials, 2022, 34(11): 5311-5319.

6.Li X, Zheng Y, Ma R, et al. Sb 掺杂的 CaZnOS 层状半导体中的宽带多模发射[J]. Science China Materials, 2022: 1-8.

7.Ma R, Wang C, Yan W, et al. Interface synergistic effects induced multi-mode luminescence[J]. Nano Research, 2022, 15(5): 4457-4465.

8.Li P, Zhang Z, Gao X, et al. Fast self-bleaching Nb2O5-based photochromics for high security dynamic anti-counterfeiting and optical storage applications[J]. Chemical Engineering Journal, 2022, 435: 134801.

9.Li X, Zheng Y, Ma R, et al. Broadband multimodal emission in Sb-doped CaZnOS-layered semiconductors[J]. Sci China Mater, 2022, 65: 1329-1336.

10.Ning J, Zheng Y, Ren Y, et al. MgF2: Mn2+: novel material with mechanically-induced luminescence[J]. Science Bulletin, 2022, 67(7): 707-715.

11.Lai J, Zhao Z, Miao Y, et al. High-brightness perovskite microcrystalline light-emitting diodes[J]. The Journal of Physical Chemistry Letters, 2022, 13(13): 2963-2968.

12.Zheng Y, Li X, Ma R, et al. Molten Salt Shielded Synthesis of Monodisperse Layered CaZnOS‐Based Semiconductors for Piezophotonic and X‐Ray Detection Applications[J]. Small, 2022, 18(12): 2107437.

13.Ma X, Wang C, Wei R, et al. Bimodal tactile sensor without signal fusion for user-interactive applications[J]. ACS nano, 2022, 16(2): 2789-2797.

14.Zhang, Xianhui, et al. "5d→ 4f transition of a lanthanide-activated MGa 2 S 4 (M= Ca, Sr) semiconductor for mechanical-to-light energy conversion mediated by structural distortion." Dalton Transactions 51.27 (2022): 10457-10465.

2021年

1.Jingjing Ning, Yuantian Zheng, Yinti Ren, Leipeng Lis, Xingqiang Shi, Dengfeng Peng*, Yanmin Yang*, MgF_:Mn't: novel material with mechanically-inducedluminescence,Science Bulletin, 2021, doi.org/10.1016/jscib.2021.12.005 1-22051313542AU pdf

2,Denofeng Peng.Mechanoluminecence materials for tactile Sensors, Book Functional Tactile Sensors: MaterialsDevices and lntegrations, Woodhead PublishingSeries in Electronic and Optical Materials, Elsevier Pubilisher, 2021, Chapter 6:

htps://do.org/10.1016/B978-0-12-820633-1.00007-3

3, Chunfeng Wang, Ronghua M, Dengfeng Peng*, Xianhu liu, Jing Li, Boru Jjin, Aixian Shan, Yu Fu, Lin Dong, Wenchao Gaos, Zhonglin Wangy, Caofeng Pan*,Mechanoluminescent hybrids from a natural resource for energy-related applications, Infomat, 2021, DO1:10.1002/inf2.122501-22051314033V53 pdf

4.Dengfeng Peng,Xianhu Liu,Caofeng Pan*, Epitaxial lift-off for controllable sinale- crvstalline perovskites, Science Buletin.2021. 66/1).61-22051314035201 pd

5.Ronghua Ma,Xioyan Wei, Chunfeng Wang,haohui Mao, Bing Chen, Yonghong Shao, Yu Fu, Keyu Yan, Dengfeng Peng*, Reproducible mechanical-to-opticalenergy conversion in Mn (ll) doped sphalerite ZnS, Journal of Luminescence, 2021, 232, 117838122051314042602 pdf

6.Xiuxia Yang, Rong liju,Xuhui Xu, Zhichao liu, Mingzi Sun, Wei Yan, Dengfeng Peng,Chao-Nan Xu, Bolong Huang, Dong Tu EFfective repeatablemechanoluminescence in heterostructured Li1-xNaxNb03:Pr3+, Small, 2021, DO: 10.1002/smll.20210344171-22051314055C13pdf

7.Yingjie Zhao, Gongxun Bais, Yougiang Huang, Yuan Liu, Dengfeng Peng4, Liang Chen, Shiging Xu, Stimuli Responsive lanthanide lons Doped LayeredPiezophotonic Microcrystals for Optical Multifunctional Sensing Applications, Nano Energy, 2021, 87, 106177

2020年

1.Ma R, Mao S, Wang C, et al. Luminescence in manganese (II)-Doped SrZn2S2O crystals from multiple energy conversion[J]. Frontiers in chemistry, 2020, 8: 752.

2.Wang C, Peng D, Pan C. Mechanoluminescence materials for advanced artificial skin[J]. Sci. Bull, 2020, 65(14): 1147-1149.

3.Zhang X, Zhao J, Chen B, et al. Tuning Multimode Luminescence in Lanthanide (III) and Manganese (II) Co‐Doped CaZnOS Crystals[J]. Advanced Optical Materials, 2020, 8(11): 2000274.

4.Peng D, Jiang Y, Huang B, et al. A ZnS/CaZnOS heterojunction for efficient mechanical‐to‐optical energy conversion by conduction band offset[J]. Advanced Materials, 2020, 32(16): 1907747.

5.Li J, Bao R, Tao J, et al. Visually aided tactile enhancement system based on ultrathin highly sensitive crack-based strain sensors[J]. Applied Physics Reviews, 2020, 7(1): 011404.

6.Ma W, Lu J, Wan B, et al. Piezoelectricity in multilayer black phosphorus for piezotronics and nanogenerators[J]. Advanced Materials, 2020, 32(7): 1905795.

7.Sun H, Guo Z, Zhu Y, et al. Single-band near-infrared upconversion emission and visible-light absorption in highly doped pseudo-perovskite oxides[J]. Solar Energy Materials and Solar Cells, 2020, 205: 110253.

8.王春枫,彭登峰,潘曹峰.先进仿生皮肤的力致发光材料[J].科学通报：英文版,2020(14):1147-1149.

2019年

1.Wang C, Dong L, Peng D, et al. Tactile sensors for advanced intelligent systems[J]. Advanced Intelligent Systems, 2019, 1(8): 1900090.

2.Xu Q, Yang Z, Peng D, et al. WS2/CsPbBr3 van der Waals heterostructure planar photodetectors with ultrahigh on/off ratio and piezo-phototronic effect-induced strain-gated characteristics[J]. Nano Energy, 2019, 65: 104001.

3.Li F, Lu J, Zhang Q, et al. Controlled fabrication, lasing behavior and excitonic recombination dynamics in single crystal CH3NH3PbBr3 perovskite cuboids[J]. Science Bulletin, 2019, 64(10): 698-704.

4.Yang Z, Lu J, ZhuGe M, et al. Controllable growth of aligned monocrystalline CsPbBr3 microwire arrays for piezoelectric‐induced dynamic modulation of single‐mode lasing[J]. Advanced Materials, 2019, 31(18): 1900647.

5.Ma W, Lu J, Yang Z, et al. Crystal-orientation-related dynamic tuning of the lasing spectra of CdS nanobelts by piezoelectric polarization[J]. ACS nano, 2019, 13(5): 5049-5057.

6.Du Y, Jiang Y, Sun T, et al. Mechanoluminescence: Mechanically Excited Multicolor Luminescence in Lanthanide Ions (Adv. Mater. 7/2019)[J]. Advanced Materials, 2019, 31(7): 1970051.

7.Du Y, Jiang Y, Sun T, et al. Mechanically excited multicolor luminescence in lanthanide ions[J]. Advanced Materials, 2019, 31(7): 1807062.

8.Sun M, Dong H, Dougherty A W, et al. Nanophotonic energy storage in upconversion nanoparticles[J]. Nano Energy, 2019, 56: 473-481.

9.曲思岑, 彭登峰. 高校室外游泳课教学分析── 体能与运动技能教学相长[J]. 教育现代化, 2019, 21.

10.Peng Y, Lu J, Peng D, et al. Dynamically modulated GaN whispering gallery lasing mode for strain sensor[J]. Advanced Functional Materials, 2019, 29(42): 1905051.

11.Wang X, Peng D, Huang B, et al. Piezophotonic effect based on mechanoluminescent materials for advanced flexible optoelectronic applications[J]. Nano Energy, 2019, 55: 389-400.

2018年

1.Sun H, Zhang Y, Liu J, et al. Reversible upconversion switching for Ho/Yb codoped (K, Na) NbO3 ceramics with excellent luminescence readout capability[J]. Journal of the American Ceramic Society, 2018, 101(12): 5659-5674.

2.Zhang Y, Liu J, Sun H, et al. Reversible luminescence modulation of Ho‐doped K0. 5Na0. 5NbO3 piezoelectrics with high luminescence contrast[J]. Journal of the American Ceramic Society, 2018, 101(6): 2305-2312.

3.Huang B, Sun M, Peng D. Intrinsic energy conversions for photon-generation in piezo-phototronic materials: A case study on alkaline niobates[J]. Nano Energy, 2018, 47: 150-171.

4.Huang B, Wu Q, Peng X, et al. One-scan fluorescence emission difference nanoscopy developed with excitation orthogonalized upconversion nanoparticles[J]. Nanoscale, 2018, 10(45): 21025-21030.