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2022年文章


  1. L. Yan*, Y. Ma, Jinhai Si, and X. Hou, "Optical limiting property and mechanism of 2D MXene Nb2CTX nanosheets," Opt. Eng. 61(2), 026108 (2022).

  2. L. Yan*, Z. Liang, Jinhai Si*, P. Gong, Y. Wang, X. Liu, J. Tong, J. Li, and X. Hou, "Ultrafast Kinetics of Chlorinated Polymer Donors: A Faster Excitonic Dissociation Path," ACS Appl. Mater. Interfaces, 14(5), 6945-6957 (2022).

  3. Y. Li, L. Yan*, Jinhai Si, Z. Liang, W. Huang, H. Ma, and X. Hou, "Nonlinear optical limiting property and carrier dynamics in tin phthalocyanine porous organic frameworks," J. Chem. Phys. 156, 054702 (2022).

  4. W. Tan *, J. Ma, Jinhai Si, Z. Huang, and X. Hou, “Femtosecond optical Kerr gate with double gate pulses: Simulation and experiment,” Optics and Laser Technology, 145, 107531 (2022).

  5. Z. Huang, W. Tan *, Jinhai Si, S. Zeng, Z. Kang and X. Hou, "High-Transmittance Femtosecond Optical Kerr Gate with Double Gate Pulses Based on Birefringence Effect," Photonics, 9(2), 71 (2022).

  6. T. Shen, T. Chen, Jinhai Si, B. Gao, W. Hu, H. Wang, and X. Hou, "Structural changes during femtosecond laser percussion drilling of high-aspect-ratio diamond microholes," Optical Engineering, 61(1), 016103 (2022).

  7. S. Zeng, Z. Li, W. Tan*, Jinhai Si, Z. Huang, and X. Hou, "Ultrafast Electron Transfer Dynamics Affected by Ligand Chain Length in InP/ZnS Core/Shell Quantum Dots," Journal of Physics Chemistry C, 126(21) 9091–9098 (2022).

  8. T. Shen, Jinhai Si*, T. Chen, Y. Zhuang, and X. Hou, "Fabrication of microgrooves in PMN-PT using femtosecond laser irradiation and acid etching," Applied Optics, 61(21), 6234-6240 (2022).

  9. R. Lv, T. Chen, X. Pham,Jinhai Si, J. Huang, Y. Hou, B. Gao, and X. Hou, "High-temperature linearly polarized single-frequency fiber lasers based on a non-polarization-maintaining FBG preparation through a femtosecond laser," Optics Letters, 47(16), 4111-4114 (2022).

  10. Y. Li, Jinhai Si*, L. Yan, Z. Fan, Z. Liang, and X. Hou, "Nonlinear optical limiting property of the carboxyl-functionalized Ti3C2 MXene nanosheets," J. Chem. Phys. 157, 164704 (2022).

  11. S. J. Zeng, W. J. Tan, Jinhai Si, L. H. Mao, J. W. Shi, Y. R. Li, and X. Hou, "Ultrafast Electron Transfer in InP/ZnSe/ZnS Quantum Dots for Photocatalytic Hydrogen Evolution," Journal of Physical Chemistry Letters, 13(39) 9096-9102 (2022).

  12. S. J. Zeng, Z. B. Li, W. J. Tan, Jinhai. Si, Y. R. Li, and X. Hou, "Ultrafast Charge Carrier Dynamics in InP/ZnSe/ZnS Core/Shell/Shell Quantum Dots," Nanomaterials, 12(21) 3817 (2022).

  13. P. P. Zhao, J. Hu, T. Chen, Jinhai Si, J. P. Wu, Y. Zhang, K. D. Li, and X. Hou, "Formation of silver wires embedded in hydrogels using femtosecond laser ablation and electroplating for strain sensing," Journal of Micromechanics and Microengineering 32(12) 125005 (2022).

  14. Li, Minjing; Yang, Tongzhen; Yang, Qing*; Fang, Zheng; Bian, Hao; Zhang, Chengjun; Hou, Xun; Chen, Feng*; Bioinspired Anti-Fogging and Anti-Fouling Artificial Compound Eyes, Advanced Optical Materials, 2022, 2200861.(Cover)

  15. Bai, Xue; Yang, Qing; Li, Haoyu; Huo, Jinglan; Liang, Jie; Hou, Xun; Chen, Feng*; Sunlight Recovering the Superhydrophobicity of a Femtosecond Laser-Structured Shape-Memory Polymer, Langmuir, 2022, 38: 4645-4656. (Cover)

  16. Liang, Jie;Shan, Chao*;Wang, Hao; Hu, Tao; Yang, Qing; Li, Haoyu; Hou, Xun; Chen, Feng*; Highly Stable and Transparent Slippery Surface on Silica Glass Fabricated by Femtosecond Laser, Advanced Engineering Materials, 2022, 2200708. (Cover)

  17. Yong, Jiale; Yang, Qing; Hou, Xun; Chen, Feng*; Nature-Inspired Superwettability Achieved by Femtosecond Lasers, Ultrafast Science, 2022, 9895418. (Cover)

  18. Wang, Shaokun; Zhang, Fan; Yang, Qing; Li, Minjing; Hou, Xun; Chen, Feng*; Chalcogenide Glass IR Artificial Compound Eyes Based on Femtosecond Laser Microfabrication, Adv. Mater. Technol, 2022, 2200741. (Cover)

  19. Yong, Jiale; Yang, Qing; Huo, Jinglan; Hou, Xun; Chen, Feng*; Underwater Gas Self-Transportation along Femtosecond Laser-Written Open Superhydrophobic Surface Microchannels (<100 µm) for Bubble/Gas Manipulation, International Journal of Extreme Manufacturing, 2022, 4: 015002. (ESI Highly Cited Paper)

  20. Zhang, Chengjun; Li, Zhikang; Li, Haoyu; Yang, Qing;* Wang, Hao; Shan, Chao; Zhang, Jingzhou; Hou, Xun; Chen, Feng*; Femtosecond Laser-Induced Supermetalphobicity for Design and Fabrication of Flexible Tactile Electronic Skin Sensor, ACS Appl. Mater. Interfaces, 2022, 14, 38328−38338.

  21. Lu, Yu; Kai, Lin; Chen, Caiyi; Yang, Qing; Meng, Yizhao; Liu, Yi; Cheng, Yang; Hou, Xun; Chen, Feng*; Nanochannels with a 18-nm feature size and ultrahigh aspect ratio on silica through surface assisting material ejection[J]. Advanced Photonics Nexus, 2022, 1(2): 026004.

  22. Kai, Lin; Chen, Caiyi; Lu, Yu; Meng, Yizhao; Liu, Yi; Cheng, Yang; Yang, Qing; Hou, Xun; Chen, Feng*; Insight on the regulation mechanism of the nanochannels in hard and brittle materials induced by sparially shaped femtosecond laser. Frontiers in Chemistry, 2022, 10:973570.

  23. Cheng, Yang; Lu, Yu; Yang, Qing;* Zhong, Jun; Xu, Mengchen; Gou, Xiaodan; Kai, Lin; Hou, Xun; Chen, Feng*; Rapid Fabrication of Wavelength-Scale Micropores on Metal by Femtosecond MHz Burst Bessel Beam Ablation, Nanomaterials, 2022, 12(24), 4378.

  24. Du, Guangqing; Lu,Yu; Dayantha Lankanath; Hou, Xun; Chen, Feng*; Molecular-Scale Plasmon Trapping via a Graphene-Hybridized Tip-Substrate System, Materials, 2022, 15, 4627.

  25. Yin, Fei; Meng, Yizhao; Yang, Qing; Kai, Lin; Liu, Yi; Hou, Xun; Lu, Yu; Chen, Feng*; High precision reconstruction for compressed femtosecond dynamics images based on the TVAL3 algorithm, Optical Materials Express, 2022, 12, 4435-4443.

  26. Zhang, Jingzhou; Zhang, Chengjun; Li, Haoyu; Cheng, Yang; Yang, Qing; Hou, Xun; Chen, Feng*; Controlling the oxidation and wettability of liquid metal via femtosecond laser for high-resolution flexible electronics, Frontiers in Chemistry, 2022, 10:965891.

  27. Fang, zheng; Cheng, Yang; Yang, Qing;* Zhang, Chengjun; Li, Minjing; Du, Bing; Hou, Xun; Chen, Feng*; Design of Metal-Based Slippery Liquid-Infused Porous Surfaces (SLIPSs) with Effective Liquid Repellency Achieved with a Femtosecond Laser, Micromachines, 2022, 13, 1160.

  28. Li, minjing; Yang, Qing;* Bian, Hao; Yang, Tongzhen; Hou, Xun; Chen, Feng*; Microlens arrays enable variable-focus imaging, Optics and Laser technology, 2022, 153: 108260.

  29. Zhang, Jialiang; Yang, Qing; Cheng, Yang; Fang, Zheng; Hou, Xun; Chen, Feng*; Slippery Liquid‐Infused Porous Surface on Metal Material with Excellent Ice Resistance Fabricated by Femtosecond Bessel Laser, Advanced Engineering Materials, 2022, 29: 1808739.

  30. Yong, Jiale; Yang, Qing; Hou, Xun; Chen, Feng*; Emerging Separation Applications of Surface Superwettability, Nanomaterials, 2022, 12: 688.

  31. Yang, Tongzhen; Li, Minjing; Yang, Qing; Lu, Yu; Cheng, Yang; Zhang, Chengjun; Du, Bing; Hou, Xun; Chen, Feng*; Femtosecond Laser Fabrication of Submillimeter Microlens Arrays with Tunable Numerical Apertures, Micromachines, 2022, 13, 1297.

  32. Zhang, Jingzhou; Zhang Yuanchen; Yong, Jiale; Hou, Xun; Chen, Feng*; Femtosecond laser direct weaving bioinspired superhydrophobic/hydrophilic micro-pattern for fog harvesting, Optics and Laser technology, 2022, 146: 107593.

  33. Zhang, Jialiang; Cheng, Yang; Yang, Qing; Liang, Jie; Fang, Zheng; Hou, Xun; Chen, Feng*; Research Progress of Femtosecond Laser Preparation of Durable Superhydrophobic Surface and Its Application(Invited). Acta Photonica Sinica,2022,51(7): 0751414.

  34. Li, Haoyu; Zhang, Chengjun; Yang, Qing; Hou, Xun; Chen, Feng*; Liquid Metal Based Flexible Electronics Fabricated by Laser and its Applications. Chinese Journal of Lasers, 2022, 49(10): 1002505.

  35. Yang, Qing; Cheng, Yang; Fang, Zheng; Zhang, Jialiang; Hou, Xun; Chen, Feng*;The preparation and applications of bio-inspired slippery surface by femtosecond laser micro-nano manufacturing. Opto-Electron Eng, 2022, 49(1): 210326

  36. hengdong Chang, Genqiang Chen, Guoqing Shao, Yanfeng Wang, Minghui Zhang, Jianing Su, Fang Lin, Wei Wang, Hong-Xing Wang, Normally-off hydrogen-terminated diamond field effect transistor with a bilayer dielectric of Er2O3/Al2O3, Diamond & Related Marials, 2022, 123, 108848.

  37. Feng Wen, Shaowei Zhang, Sijia Hui, Hanghang Ma, Sijia Wang, Huapeng Ye, Wei Wang, Tianfei Zhu, Yanpeng Zhang, Hongxing Wang, Terahertz tunable optically induced lattice in the magnetized monolayer graphene, Optics Express, vol.30, no.2/17, Jan. 2022, 2852-2862.

  38. Minghui Zhang, Fang Lin, Wei Wang, Feng Wen, Genqiang Chen, Shi He, Yanfeng Wang, Shuwei Fan, Renan Bu, Hongxing Wang, HfAlOx/Al2O3 bilayer dielectrics for a field effect transistor on a hydrogen-terminated diamond[J], Materials, 2022,15, 446.

  39. Minghui Zhang, Wei Wang, Feng Wen, Fang Lin, Genqiang Chen, Shi He, Yanfeng Wang, Shuwei Fan, Renan Bu, Tai Min, Hongxing Wang, Large |VTH| of normally-off field effect transistor with Yttrium gate material directly deposited on Hydrogen-terminated diamond[J], IEEE Transactions on Electron Devices, 2022, 69(7):3563-3567.

  40. Juan Wang, Guoqing Shao, Qi Li, Genqiang Chen, Xiuliang Yan, Zhiqiang Song, Yanfeng Wang, Ruozheng Wang, Wei Wang, Shuwei Fan, and Hong-Xing Wang, Vertical Diamond Trench MOS Barrier Schottky Diodes With High Breakdown Voltage[J], IEEE Transactions on Electron Devices, 2022, 69(11):6231-6235.

  41. Qi Li, Juan Wang, Guoqong Shao, Genqiang Chen, Shi He, Qianwen Zhang, Shumiao Zhang, Ruozheng Wang, Shuwei Fan, Hong-Xing Wang, Breakdown Voltage Enhancement of Vertical Diamond Schottky Barrier Diode With Annealing Method and Al2O3 Field Plate Structure[J], IEEE Electron Device Lett. 43 (2022) 1937–1940.

  42. Genqiang Chen, Wei Wang, Fang Lin, Minghui Zhang, Qiang Wei, Cui Yu,Hong-Xing Wang. (2022). Electrical Characteristics of Diamond MOSFET with 2DHG on a Heteroepitaxial Diamond Substrate[J]. Materials, 15(7), 2557

  43. Genqiang Chen, Wei Wang, Shi He,Juan Wang, Shumiao Zhang, Minghui Zhang,Hong-Xing Wang. Leakage current reduction of normally off hydrogen-terminated diamond field effect transistor utilizing dual-barrier Schottky gate[J]. Journal of Applied Physics, 2022(1):132.

  44. Genqiang Chen, Shumiao Zhang, Minghui Zhang, Qi Li, Ruozheng Wang, Shi He, Wei Wang, Hong-Xing Wang. Normally-off CH Diamond FETs With Partial Al/C-O Diamond Junction Attaining Low off-State Current[J]. IEEE Transactions on Electron Devices, 2022, 69(12): 6582-6586.

  45. Shumiao Zhang, Juan Wang, Qi Li, Guoqing Shao, Genqiang Chen, Shi He, Hong-Xing Wang. Improved-Performance Diamond Schottky Barrier Diode With Tin Oxide Interlayer[J]. IEEE Transactions on Electron Devices, 2022, 69(11): 6260-6264.

  46. Shumiao Zhang, Qi Li, Juan Wang, Ruozheng Wang, Guoqing Shao, Genqiang Chen,Hong-Xing Wang. (2022). High Breakdown Electric Field Diamond Schottky Barrier Diode With SnO2 Field Plate[J]. IEEE Transactions on Electron Devices, 69(12), 6917-6921.

  47. Shi He,Genqiang Chen,Xinxin Han,Wei Wang,Xiaohui Chang,Qi Li,Qianwen Zhang,Yan-Feng Wang,Minghui Zhang,Tianfei Zhu,and Hong-XingWang Solution-processed tin oxide thin film for normally-off hydrogen terminated diamond field effect transistor[J]. Applied Physics Letters, 2022, 120(13): 132102.

  48. Shi He, Wei Wang, Genqiang Chen, Shumiao Zhang, Qi Li, Qianwen Zhang, Xiaohui Chang, Yan-Feng Wang, Minghui Zhang, Hong-Xing Wang. Small Subthreshold Swing Diamond Field Effect Transistors With SnO2 Gate Dielectric[J]. IEEE Transactions on Electron Devices, 2022, 69(8): 4427-4431.

  49. Shi He, Yan-Feng Wang, Genqiang Chen, Juan Wang, Qi Li, Qianwen Zhang, Ruozheng Wang, Minghui Zhang, Wei Wang, Hong-Xing Wang. Normally-off Hydrogen-Terminated Diamond Field-Effect Transistor with SnOx Dielectric Layer Formed by Thermal Oxidation of Sn[J]. Materials, 2022, 15(14): 5082.

  50. Bangqiang Xu, Qianwen Zhang, Xiaohui Chang, Dan Zhang, Genqiang Chen, Shi He, Yanfeng Wang, Yangmeng Feng, Hong-Xing Wang. Detection of Carbohydrate Antigen 19-9 by a Diamond Solution-Gate Field-Effect Transistor Sensor[J], Mater. Lett. 318 (2022) 132116.

  51. Qianwen Zhang, Xiaohui Chang, Bangqiang Xu, Yanfeng Wang, Dan Zhang, Yangmeng Feng, Shi He, Genqiang Chen, Qi Li, Juan Wang, Hong-Xing Wang. Detection of Glucose Using Diamond Solution-Gate Field-Effect Transistor[J], IEEE Trans. Electron Devices. 69 (2022) 4534–4539.

  52. Qianwen Zhang, Yuxiang Du, Xiaohui Chang, Bangqiang Xu, Genqiang Chen, Shi He, Dan Zhang, Qi Li, Juan Wang, Ruozheng Wang and Hong-Xing Wang. Partly-O-Diamond Solution-Gate Field-Effect Transistor as an Efficient Biosensor of Glucose[J]. Electrochem. Soc. https://doi.org/10.1149/1945-7111/aca8d4.

  53. Jianing Su, Ruozheng Wang, Hong-Xing Wang, Huiqing Fan, Investigation on magnetic properties of W-doped diamond via first-principles[J], Diamond and Related Materials, 129 (2022) 109306.

  54. Jianing Su, Genqiang Chen, Wei Wang, Han Shi, Shi He, Xiaoyong Lv, Yanfeng Wang, Minghui Zhang, Ruozheng Wang, Hong-Xing Wang, Electrical characteristics of normally-off hydrogen-terminated diamond field effect trans

  55. Chen, J.; Yang, Y.;Dong, H.*;Li, J.*;Zhu, X.; Xu, J.; Pan, F.; Yuan, F.; Dai, J.;Jiao, B.;Hou, X.; Alex K.-Y. Jenand Wu, Z.*. Highly effici-

  56. ent and stable perovskite solar cells enabled by low-dimensional perovskitoids.Science Advances, 2022(DOI: 10.1126/sciadv.abk2722)

  57. Li, L.; He, X.; Xu, D.; Zhao, C.; Jiao, B.; Zuo, X.; Yu, Y. * and Wu, Z.*. Ultra-thick inverted green organic light-emitting diodes for high power efficiency over 300 lm/W.Organic Electronics, 101 (2022) 106414

  58. Liu, X.; Yuan, F.*; Zhu, C.; Li, J.*; Lv, X.; Xing, G.; Wei, Q.; Wang, G.; Dai, J.; Dong, H.; Xu, J.; Jiao, B. and Wu, Z.*. Near-unity blue luminance from lead-free copper halides for light-emitting diodes.Nano Energy, 91 (2022) 106664

  59. Zhenhuan Tian,J.Bennett,J.Yang,T.Lawrie,W.Elmadih,A.Bardalai,C.Gerada,Jian Zhu,D.Chronopoulos,Experimental investigation of mechanical, acoustic and hybrid,Engineering Structures

  60. Li, Qiang; Zhang, QF; Chen, RS ; Zhang, HR ; Wang, MD ; Zhu, JP ; Wang, XL ; Liu, YH ; Yun, F,Wafer-Scale Growth of Fe-Doped Hexagonal Boron Nitride (hBN) Films via Co-Sputtering,CRYSTALS

  61. Qiang Li,Mingdi Wang,Yunhe Bai,Qifan Zhang,Haoran Zhang,Zhenhuan Tian,Yanan Guo,Jingping Zhu,Yuhuai Liu,Feng Yun,Tao Wang,Yue Hao,Two-Inch Wafer-Scale Exfoliation of Hexagonal Boron Nitride Films Fabricated by RF-Sputtering, Advanced functional materials

  62. Qifan Zhang, Qiang Li, Weihan Zhang, Haoran Zhang, Feng Zheng, Mingyin Zhang, Peng Hu, Mingdi Wang, Zhenhuan Tian, Yufeng Li, Yuhuai Liu, Feng Yun, Phase transition and bandgap engineering in B1-xAlxN alloys: DFT calculations and experiments, Applied Surface Science

  63. Zhaoyang Zhang, Yuan Feng, Feng Li, Sergei Koniakhin, Changbiao Li, Fu Liu, Yanpeng Zhang, Min Xiao, G.Malpuech,and D. Solnyshkov,Angular-dependent Klein tunneling in photonic grapheme,Phys. Rev. Lett. 129(23), 233901

  64. Peng Li, Yaxin Guo, Ao Liu, Xin Yue, Taoli Yuan, Jingping Zhu, Yanpeng Zhang, and Feng Li,Deterministic relation between optical polarization and lattice symmetry revealed in ion-doped single microcrystals,ACS Nano 16(6), 9535-9545

  65. Changbiao Li, Qingsong Yu, Yanpeng Zhang, Min Xiao, and Zhaoyang Zhang,Optical isolation with optical parametric amplification in an atomic system,Laser Photonics Rev. 16, 2200267

  66. Yongsheng Wang, Yuhao Ren, Xiaoxuan Luo, Bo Li, Zaoyu Chen, Zhenzhi Liu, Fu Liu, Yan Cai, Yanpeng Zhang, Jin Liu, and Feng Li,Manipulating cavity photon dynamics by topologically curved space,Light: Science & Applications

  67. Yuan Zhao, Muhammad Imran, Anas Mujahid, Irfan Ahmed, Li Changbiao, Faisal Nadeem, and Yanpeng Zhang,Temporal interaction of hybrid signals in various phases of Eu3+: BiPO4 through photon-phonon dressing,New J. Phys. 24(8), 083037

  68. Jinyang Li, Jianfeng Zhu, Muhammad Imran, Huanrong Fan, Anas Mujahid, Faisal Nadeem, Peng Li, and Yanpeng Zhang,Superior atomic coherence time controlled by crystal phase transition and optical dressing,Opt. Lett. 47(9), 2310-2313

  69. Zhaoyang Zhang, Yuan Feng, Hua Zhong,Milivoj R. Belic, Yiqi Zhang, Shaohuan Ning, Shun Liang, Yanpeng Zhang, and Min Xiao,Experimental Demonstration of Optical Bloch Oscillation in Electromagnetically Induced Photonic Lattices,Fundamental Research2(3), 401-404

  70. Tianlun Li, Xiaodie Li, Duorui Gao, Jianyong Mao, Yaping Hou, Hui Chen, Feng Li, Yanpeng Zhang, Jixiang Fang, and Lei Zhang,Light modulation based on the enhanced Kerr effect in molybdenum disulfide nanostructures with curved features,Phys. Chem. Chem. Phys. 24, 12208-12213

  71. Yuan Zhao, Anas Mujahid, Hasnain Ali, Yaxin Guo, Huanrong Fan, Faisal Nadeem, Zhou Feng, Muhammad Shehbaz, and Yanpeng Zhang,Self-dressing Fano interference controlled by various crystal phase transition,J. Lumin.247, 118855

  72. Yunfan Xu, Lei Zhang, Bobo Du, Hui Chen, Yaping Hou, Tianlun Li, Jianyong Mao, and Yanpeng Zhang,,Quasi-BIC based low-voltage phase modulation on lithium niobite metasurface,IEEE Photon. Tech. Lett. 34(20), 1077-1080

  73. Jiawei Li, Wei Li, Mengqi Niu, Yixing Lin, Changbiao Li, Yin Cai, and Yanpeng Zhang,Corrigendum to Generation of multimode quantum correlation with energy-level cascaded four-wave mixing processes,[Ann. Phys. 422 (2020) 168316]", Ann. Phys. 439, 168765

  74. Zhaoyang Zhang, Yuan Feng, Shaohuan Ning, G.Malpuech, D. D. Solnyshkov, Zhongfeng Xu,Yanpeng Zhang,and Min Xiao,Imaging lattice switching with Talbot effect in reconfigurable non-Hermitian photonic grapheme,Photonics Research 10(4), 958-964

  75. Anas Mujahid, Muhammad Imran, Huanrong Fan, Taoli Yuan, Faisal Nadeem, Zhou Feng, Irfan Ahmed, and Yanpeng Zhang,emporal and spectral hybrid bound state in continuum and its reliance on the correlation,Phys. Chem. Chem. Phys. 24, 12457-12464

  76. Yuan Zhao, Huanrong Fan, Faizan Raza, Irfan Ahmed, Jintian Li, Jiajia Wei, Changbiao Li, and Yanpeng Zhang,Correlation interference demultiplexer controlled by phase transition for Pr3+/Eu3+: YPO4,Opt. Materials 129, 112423

  77. Ruimin Wang, Yuan Zhao, Zhou Feng, Jiajia Wei, Jiaxuan Wei, Huanrong Fan, Qingyang Ji, and Yanpeng Zhang,Spectral Line-shape Controlled by Nonlinear Fano interference in Eu3+-doped Microcrystals,Opt. Materials 133, 112965

  78. Bobo Du, Hua Lu, Lei Zhang, and Yanpeng Zhang,Fiber-integrated Tamm plasmon system J. Lightwave Technol. 40(15), 5280-5285

  79. Wei Gao, Wenhui Fan, Pei Ju, Gang Li, Yiqi Zhang, and Yanpeng Zhang,Thermally-induced transverse mode instability: Hopf bifurcation in high-power fiber laser,Results in Phys. 43, 106098

  80. Shun Liang, Qingsong Yu, Xing Lei, Shaohuan Ning, Changbiao Li, Yanpeng Zhang, andZhaoyang Zhang,Experimental Realization of Reconfigurable Photonic Lattices in Coherent Rydberg Atomic Vapors,Photonics 9, 422

  81. Changbiao Li, Yufeng Li, Wei Li, Kangkang Li, Yuliang Liu, Yin Cai, and Yanpeng Zhang,Generation of tripartite squeezed state by cascaded four-wave mixing in single hot rubidium atomic system,New J. Phys. 24(9), 093022

  82. Yuliang Liu, Jiajia Wei, Mengqi Niu, Yixing Lin, Zhili Chen, Jin Yan, Binshuo Luo, Yin Cai, and Yanpeng Zhang,Atomic-coherence-assisted multipartite entanglement generation with dressing-energy-level-cascaded four-wave mixing,Phys. Rev. A 106, 043709

  83. Wenqiang Qin, Jiawei Li, Zhili Chen, Jiajia Wei, Yonglin Bai, Yin Cai, and Yanpeng Zhang,Multimode Quantum Squeezing Generation via multiple Four-Wave-Mixing within a single atomic vapor,J. Opt. Soc. Am. B 39(10), 2769-2778

  84. Jiawei Li, Jianhua Zeng, Feng Li, Yanpeng Zhang, and Yin Cai,Optimal Bright Multimode Quantum Squeezing via Multi-seeding Energy-level Cascaded Four-wave mixing,Opt. Express 30(22), 39762-39774

  85. Qingsong Yu, Zhenzhi Liu, Dawei Guo, Shun Liang, Yanpeng Zhang, andZhaoyang Zhang,Optically-Induced Symmetry Switching in a Reconfigurable Kagome Photonic Lattice: from Flatband to Type-III Dirac Cones,Nanomaterials 12, 3222

  86. Huanrong Fan, Faizan Raza, Irfan Ahmed, Muhammad Imran, Faisal Nadeem, Changbiao Li, Peng Li, and Yanpeng Zhang,“Photon-phonon atomic coherence interaction of non-linear signals in various phase transitions Eu3+: BiPO4,Nanomaterials 12(23), 4304

  87. Wenqi Xu, Hui Wang, Daohong Xie, Junling Che, and Yanpeng Zhang,Hierarchy of Nonlinear Entanglement Dynamics for Continuous Variables,Phys. Rev. Lett. 127(15), 150502

  88. Haoxiang Li, Jingping Zhu, Jinxin Deng, Fengqi Guo, Liu Yue, Jian Sun, Yunyao Zhang, and Xun Hou,Visibility enhancement of underwater images based on polarization common-mode rejection of a highly polarized target signal,Optics Express

  89. Xiangzhe Zhang, Liqing Huang, Jingping Zhu , Ning Zhang, Kang Zong, Lipeng Zhai, Yu Zhang, Yakun Cai, and Huimin Wang,Exact optical path difference and complete performance analysis of a spectral zooming imaging spectrometer,Optics Express

  90. 朱京平,邓金鑫,李浩翔,郭奉奇,侯洵,浑浊介质中偏振差分成像技术发展及展望(特邀),光电技术应用

  91. 赵元辰,朱京平,郭奉奇,李浩翔,侯洵,空间目标材质偏振光谱特性规律研究(特邀),光电技术应用

  92. Asif, S.; Yi, W*.; Ul Ain, Q.; Hou, J.; Yi, T.; Si, J., Improving Effectiveness of Different Deep Transfer Learning-Based Models for Detecting Brain Tumors From MR Images. Ieee Access 2022, 10, 34716-34730.

  93. Abbas, S.; Yi, W*.; Yoo, S.; Khalid, A.; Bhalli, Z.; Si, J.; Hou, X., Highly Efficient Response of Ammonia Gas Sensor Based on Surfactant-Free Sorted-Semiconducting Single-Walled Carbon Nanotubes at Room Temperature. Physica Status Solidi a-Applications and Materials Science 2022.

  94. Bai, L.; Yi, W*.; Chen, J.; Wang, B.; Tian, Y.; Zhang, P.; Cheng, X.; Si, J.; Hou, X.; Hou, J., Two-Stage Targeted Bismuthene-Based Composite Nanosystem for Multimodal Imaging Guided Enhanced Hyperthermia and Inhibition of Tumor Recurrence. ACS applied materials & interfaces 2022, 10.1021/acsami.2c01128.

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