[01] | Yi Chen, Simeng Zhang, Ying Tian, Chenxia Li, Wenlong Huang, Yixin Liu, Yongxing Jin, Bo Fang, Zhi Hong, Xufeng Jing,Focus control of wide-angle metalens based on digitally encoded metasurface. Opto-Electron Adv 7, 240095 (2024). DOI: 10.29026/oea.2024.240095
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[02] | Tao, Y; Zhang, DQ; Jin, ZW; Pan, GM; Qin, JY; Hong, Z; Fang, B; Shu, FZ, Tunable third harmonic generation based on high-Q polarization-controlled hybrid phase-change metasurface Nanophotonics DOI: 10.1515/nanoph-2024-0113
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[03] | Liu, Xiaoxuan; Xiao, Binggang; Qin, Jianyuan, Terahertz Sensing Based on Floating Bilayer Metasurface with Toroidal Dipole Resonance Toward Ultra-High Sensitivity, Adv. Opt. Mater. 2400785 (2024), DOI:10.1002/adom.202400785.
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[04] | Bowen Zeng, Chenxia Li, Bo Fang, Zhi Hong, Xufeng Jing*. Flexible tuning of multifocal holographic imaging based on electronically controlled metasurfaces. Photonics Research, 12(1), 61-69(2024).
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[05] | Jiang, Jie; Fang, Bo; Li, Chenxia; Hong, Zhi; Jing, Xufeng, Improvement of terahertz beam modulation efficiency for baseless all-dielectric coded gratings, Photonics Research 11, 1738(2023).
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[06] | Ke, Lan; Li, Chenxia; Zhang, Simeng; Fang, Bo; Tang, Ying; Hong, Zhi; Jing, Xufeng, Tight focusing field of cylindrical vector beams based on cascaded low-refractive index metamaterials, Nanophotonics 12, 3563-3578(2023).
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[07] | Fang, Bin; Wang, Zhizhang; Li, Yantao; Ji, Jitao; Xi, Kelei; Cheng, Qingqing; Shu, Fangzhou; Jin, Zhongwei; Hong, Zhi; Zhan, Chunlian, Spin-decoupled meta-coupler empowered multiplexing and multifunction of guided wave radiation, Photonics Research 11, 2194(2023)
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[08] | Yu, Xinyao; Li, Fanghao; Lang, Tingting; Qin, Jianyuan; Ma, Xiao, Ultrasensitive tunable terahertz lithium niobate metasurface sensing based on bound states in the continuum, Photonics Research 11, 2168(2023)
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[09] | Cen, Wenyang; Lang, Tingting; Wang, Jinfeng; Xiao, Meiyu, High-Q Fano Terahertz resonance based on bound states in the continuum in All-dielectric metasurface, Appl. Surf. Sci. 575, 151723(2022).
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[10] | Fang, B; Feng, DT; Chen, P; Shi, LJ; Cai, JH; Li, JM; Li, CX; Hong, Z; Jing, XF, Broadband cross-circular polarization carpet cloaking based on a phase change material metasurface in the mid-infrared region, Front. of Physics 17, 53502(2022).
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[11] | Jing, Xufeng; Qin, Guihong; Zhang, Peng, Broadband silicon-based tunable metamaterial microfluidic sensor, Photonics Research 10, 2876(2022).
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[12] | Pan, Gui-Ming; Yang, Li-Feng; Shu, Fang-Zhou; Meng, Yan-Long; Hong, Zhi; Yang, Zhong-Jian, Tailoring magnetic dipole emission by coupling to magnetic plasmonic anapole states, Photonics Research 10, 2032(2022).
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[13] | Pengfei Wang, Fengyan He, Jianjun Liu, Fangzhou Shu, Bin Fang, Tingting Lang, Xufeng Jing, and Zhi Hong, Ultra-high-Q resonances in terahertz all-silicon metasurfaces based on bound states in the continuum, Photonics Research 10, 2743(2022).
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[14] | Wang, Yulin; Han, Zhanghua; Du, Yong; Qin, Jianyuan; Ultrasensitive terahertz sensing with high-Q toroidal dipole resonance governed by bound states in the continuum in all-dielectric metasurface, Nanophotonics 10, 1295(2021).
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[15] | Pan, Gui-Ming; Shu, Fang-Zhou; Wang, Le; Shi, Liping; Evlyukhin, Andrey B.; Plasmonic anapole states of active metamolecules, Photonics Research 9, 822(2021).
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[16] | Xiangjun Li, Jie Yin, Jianjun Liu, Fangzhou Shu, Tingting Lang, Xufeng Jing, Zhi Hong, Resonant transparency of a planar anapole metamaterial at terahertz frequencies, Photonics Research 9, 125(2021).
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[17] | Dong Yang, Karol Horodecki, and Andreas Winter, Distributed Private Randomness Distillation, Phys. Rev. Lett. 123, 170501(2019).
|
[18] | Ting Bu, Kejian Chen, Hong Liu, Jianjun Liu, Zhi Hong, and Songlin Zhuang, Location-dependent metamaterials in terahertz range for reconfiguration purposes, Photonics Research 4, 122(2016)
|
[19] | A. Winter and Dong Yang, Operational resource theory of coherence, Phys. Rev. Lett. 116, 120404(2016).
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[20] | Mark M. Wilde; Andreas Winter; Dong Yang, Strong Converse for the Classical Capacity of Entanglement-Breaking and Hadamard Channels via a Sandwiched Renyi Relative Entropy, Communications in Mathematical Physics 331, 593(2014).
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[21] | F. Brandao, J. Eisert, M. Horodecki, D. Yang, Entangled inputs cannot make imperfect quantum channels perfect, Phys. Rev. Lett. 106, 230502(2011).
|
[22] | Dong Yang and Jens Eisert, Entanglement Combing, Phys. Rev. Lett. 103, 220501(2009).
|
[23] | Dong Yang, Michal Horodecki, and Z. D. Wang, An Additive and Operational Entanglement Measure: Conditional Entanglement of Mutual Information, Phys. Rev. Lett. 101, 140501(2008).
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