[1] KLITZING K V, DORDA G, PEPPER M. New method for high-accuracy determination of the fine-structure constant based on quantized hall resistance[J]. Physical Review Letters, 45, 494-497(1980).

[2] HALDANE F D M, RAGHU S. Analogs of quantum-Hall-effect edge states in photonic crystals[J]. Physical Review A, 78, 33834(2008).

[3] JOHN S. Strong localization of photons in certain disordered dielectric superlattices[J]. Physical Review Letters, 58, 2486-2489(1987).

[4] YABLONOVITCH E. Inhibited spontaneous emission in solid-state physics and electronics[J]. Physical Review Letters, 58, 2059-2062(1987).

[5] JOANNOPOULOS J D, JOHNSON S G, WINN J N et al[M]. Photonic crystals: molding the flow of light-second edition(2008).

[6] PRANGE M R E, GIRVIN S M, E ,R et al. Girvin-the quantum hall effect[J]. Il Nuovo Cimento B (1971-1996), 109, 211-212(1994).

[7] LYUBCHANSKII I L, DADOENKOVA N N, LEE Y P et al. Photonic crystals based on functional materials[J]. 2011 13th International Conference on Transparent Optical Networks, 1-2(2011).

[8] WANG Zheng, CHONG Yidong, JOANNOPOULOS J D et al. Observation of unidirectional backscattering-immune topological electromagnetic states[J]. Nature, 461, 772-775(2009).

[9] WANG Zheng, CHONG Y D, JOANNOPOULOS J et al. Reflection-free one-way edge modes in a gyromagnetic photonic crystal[J]. Physical Review Letters, 100, 13905(2008).

[10] HE Lingjuan, SHEN Qian, XU Jie et al. One-way edge modes in a photonic crystal of semiconductor at terahertz frequencies[J]. Scientific Reports, 8, 8165(2018).

[11] KHANIKAEV A B, BARYSHEV A V, INOUE M et al. One-way electromagnetic Tamm states in magnetophotonic structures[J]. Applied Physics Letters, 95, 423(2009).

[12] RAGHU S, HALDANE F D M. Possible Realization of directional optical waveguides in photonic crystals with broken time-reversal symmetry[J]. Physical Review Letters, 100, 13904(2008).

[13] AO Xianyu, LIN Zhifang, CHAN C T. One-way edge mode in a magneto-optical honeycomb photonic crystal[J]. Physical Review B, 80, 33105(2009).

[14] FU Jinxin, LIU Rongjuan, LI Zhiyuan. Robust one-way modes in gyromagnetic photonic crystal waveguides with different interfaces[J]. Applied Physics Letters, 97, 41112(2010).

[15] HALPERIN B I. Quantized Hall conductance, current-carrying edge states, and the existence of extended states in a two-dimensional disordered potential[J]. Physical Review B, 25, 2185(1982).

[16] LIU Kexin, SHEN Linfang, HE Sailing. One-way edge mode in a gyromagnetic photonic crystal slab[J]. Optics Letters, 37, 4110-4112(2012).

[17] HE Lingjuan, SHEN Linfang, DENG Xiaohua et al. One-way edge modes in truncated semiconductor photonic crystal at terahertz frequencies[J]. Journal of Optics, 21, 65802(2019).

[18] YANG Yihao, GAO Zhen, XUE Haoran et al. Realization of a three-dimensional photonic topological insulator[J]. Nature, 565, 622-626(2019).

[19] ALÙ A, TRETYAKOV S, SOUNAS D et al. Electromagnetic nonreciprocity[J]. Physical Review Applied, 10, 47001(2018).

[20] BRION J J, WALLIS R F, HARTSTEIN A et al. Theory of surface magnetoplasmons in semiconductors[J]. Physical Review Letters, 28, 1455-1458(1972).

[21] HARTSTEIN A, BURSTEIN E, MARADUDIN A A et al. Surface polaritons on semi-infinite gyromagnetic media[J]. Journal of Physics C: Solid State Physics, 6, 1266(1973).

[22] YU Zongfu, VERONIS Georgios, WANG Zheng et al. One-way electromagnetic waveguide formed at the interface between a plasmonic metal under a static magnetic field and a photonic crystal[J]. Physical Review Letters, 100, 23902(2008).

[23] KUZMIAK V, EYDERMAN S, VANWOLLEGHEM M. Controlling surface plasmon polaritons by a static and/or time-dependent external magnetic field[J]. Physical Review B, 86, 45403(2012).

[24] HU Bingzhi, WANG Qijie, ZHANG Ying. Broadly tunable one-way terahertz plasmonic waveguide based on nonreciprocal surface magneto plasmons[J]. Optics Letters, 37, 1895-1897(2012).

[25] ZHANG Xiaogang, LI Wei, JIANG Xunya. Confined one-way mode at magnetic domain wall for broadband high-efficiency one-way waveguide, splitter and bender[Z]. Applied Physics Letters, 100, 041108(2012).

[26] SHEN Linfang, YOU Yun, WANG Zhuoyuan et al. Backscattering-immune one-way surface magnetoplasmons at terahertz frequencies[J]. Optics Express, 23, 950-962(2015).

[27] TSAKMAKIDIS K L, SHEN L, SCHULZ S A et al. Breaking Lorentz reciprocity to overcome the time-bandwidth limit in physics and engineering[J]. Science, 356, 1260-1264(2017).

[28] TANG Yuxiang, ZHANG Yanbin, LIU Qirui et al. Interacting plexcitons for designed ultrafast optical nonlinearity in a monolayer semiconductor[J]. Light: Science & Applications, 11, 94(2022).

[29] FENG Mingming, ZHANG Baoqing, LING Haotian et al. Active metal-graphene hybrid terahertz surface plasmon polaritons[J]. Nanophotonics, 11, 3331-3338(2022).

[30] FAN Li, WANG Jian, VARGHESE L et al. An all-silicon passive optical diode[J]. Science, 335, 447-450(2012).

[31] LIN Xusheng, YAN Junhu, WU Lijun et al. High transmission contrast for single resonator based all-optical diodes with pump-assisting[J]. Optics Express, 16, 20949-20954(2008).

[32] LEONARDO D, JONATHAN M S, MICHAEL T M W et al. Microresonator isolators and circulators based on the intrinsic nonreciprocity of the Kerr effect[J]. Optica, 5, 279-282(2018).

[33] SINGH N, KÄRTNER F X. Nonlinear Mach-Zehnder interferometer isolator[J]. Optics Express, 30, 5973-5980(2022).

[34] LI Enze, DING Dongsheng, YU Yichen et al. Experimental demonstration of cavity-free optical isolators and optical circulators[J]. Physical Review Research, 2, 33517(2020).

[35] DONG Mingxin, XIA Keyu, ZHANG Weihang et al. All-optical reversible single-photon isolation at room temperature[J]. Science Advances, 7, e8924(2021).

[36] ZHONG Hua, XIA Shiqi, ZHANG Yiqi et al. Nonlinear topological valley Hall edge states arising from type-Ⅱ Dirac cones[J]. Advanced Photonics, 3, 56001(2021).

[37] COTRUFO M, MANN S A, MOUSSA H et al. Nonlinearity-induced nonreciprocity-part Ⅱ[J]. IEEE Transactions on Microwave Theory and Techniques, 69, 3584-3597(2021).

[38] COTRUFO M, MANN S A, MOUSSA H et al. Nonlinearity-induced nonreciprocity—part Ⅰ[J]. IEEE Transactions on Microwave Theory and Techniques, 69, 3569-3583(2021).

[39] ZOLLER P, LODAHL P, MAHMOODIAN S et al. Chiral quantum optics[J]. Nature, 541, 473-480(2017).

[40] LAN Yanting, SU Wanjun, WU Huaizhi et al. Nonreciprocal light transmission via optomechanical parametric interactions[J]. Optics Letters, 47, 1182-1185(2022).

[41] HUANG Xinyao, LU Cuicui, LIANG Chao et al. Loss-induced nonreciprocity[J]. Light: Science & Applications, 10, 30(2021).

[42] ZHANG Xulin, YU Feng, CHEN Zeguo et al. Non-Abelian braiding on photonic chips[J]. Nature Photonics, 16, 390-395(2022).

[43] HUANG Can, ZHANG Chen, XIAO Shumin et al. Ultrafast control of vortex microlasers[J]. Science, 367, 1018-1021(2020).

[44] TANG Jiangshan, CHEN Mingyuan, NORI F et al. Quantum squeezing induced optical nonreciprocity[J]. Physical Review Letters, 128, 83604(2022).

[45] GUO Qiushi, SEKINE R, LEDEZMA L et al. Femtojoule femtosecond all-optical switching in lithium niobate nanophotonics[J]. Nature Photonics, 16, 625-631(2022).

[46] KUTSAEV S V, KRASNOK A, ROMANENKO S N et al. Up-and-coming advances in optical and microwave nonreciprocity: from classical to quantum realm[J]. Advanced Photonics Research, 2, 2000104(2021).

[47] NIE W, TANG L, CHEN M et al. Nonreciprocal single-photon band structure[J]. Physical Review Letters, 128, 203602(2022).