胡昊博士, 教授/博导, 2023年入选国家重大人才工程A类青年人才,  江苏省特聘教授。

2016年本科毕业于浙江大学光电科学与工程学院；2020年博士毕业于新加坡南洋理工大学电气与电子工程学院；2020-2023年在新加坡南洋理工大学电气与电子工程学院担任博士后；2023年4月加入南京航空航天大学电子信息工程学院担任特聘研究员A类职务；2024年12月晋升为长聘教授；2025年4月任微波光子技术研究所副所长。

主要从事新型人工超构材料的机理及应用研究，致力于创新自由电子辐射、拓扑物理、时变材料、量子非局域等理论，发展片上光源、下一代小型化高能粒子探测器等新型光子器件，开创拓扑扩散学、时空拓扑学新领域。至今共发表学术论文四十余篇（SCI论文47篇）, 总引用达900余次。以第一、共一或通讯作者身份在国内外高影响力期刊发表论文23篇，包括2篇Advanced Materials、1篇Nature Communications、1篇Physical Review X、1篇eLight、3篇Laser & Photonics Reviews、1篇Advanced Science、1篇Nanophotonics、2篇ACS Photonics和1篇Photonics Research等。这些成果被Light： Science & Applications亮点报道1次，入选eLight 期刊Featured Article 1次、入选Laser & Photonics Reviews期刊封底1次、入选ACS Photonics期刊封面1次，被众多国内外知名专业科技网站（如Phys.org、EurekAlert!、Mirage News、Azooptics.com、Space Daily、 Florida News Times、DayToNews、Funtitech、Verve Times、中国光学、两江科技、科研留声机、天玑算等）深度正面报道。目前主持国家级、省部级等科研/人才项目累计十余项。

基于此，课题组主要的研究方向有：

（1）自由电子辐射器件：基于超构材料的奇异电磁特性，调控自由电子辐射性质，突破自由电子辐射在能量、阈值、带宽、方向等方面的物理极限，研发新一代高能粒子探测器和可集成自由电子辐射源。相关工作发表于eLight, Nature Communications, Physical Review X, Advanced Science等国际期刊。

（2）动态可调光电子器件：在时间维度调控光和物质相互作用，突破传统光电子器件（如放大器、激光器、隔离器）的增益、带宽、隔离度等物理极限）。相关工作发表于Laser & Photonics Reviews, ACS Photonics等国际期刊。

（3）拓扑器件：通过推广和应用拓扑能带理论，增强传统器件的工作稳定性。相关工作发表于Advanced Materials等国际期刊。

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荣誉和奖励

[10] 南京航空航天大学电子信息工程学院“学科建设先进个人”, 2024

[9] 南京航空航天大学“五好”导学团队, 2024

[8] 南京航空航天大学微格教学专项培训“优秀学员”, 2024

[7] 南京市紫金山英才C类, 2024

[6] 国家重大人才工程A类青年项目入选者, 2023

[5] 江苏省特聘教授, 2023

[4] 南京市人社部“留学人员科技活动项目择优资助计划”入选者, 2023

[3] 国家优秀自费留学生奖学金获得者, 2020

[2] Gold Student Paper Award, IEEE Photonics Society Singapore Chapter, 2020

[1] Best Student Paper Award （1st winner）, PIERS Xiamen, 2019

学术服务

[14] 第一届全国光电融合大会“材料与器件”专题委员，杭州, 中国, 2025年5月24日-26日

[13] 第二届中国光学工程学会青年科学家大会“海外青年科学家交流会”专题主席，宁波, 中国, 2025年4月25日-27日

[12] Session organizer for conference session “Nonlinear and spatiotemporal metamaterials/metasurfaces,” 2024 IEEE MTT-S International Microwave Workshop Series on Advanced Materials and Processes for RF and THz Applications (IMWS-AMP Nanjing, 2024)

[11] Guest editor for special issue “Design and applications of reconfigurable antenna for 5G communication,” Electronics, 2024

[10] Session organizer for conference session “Integrated metasurfaces/metamaterials on photonic platform,” 2024 International Conference on Metamaterials, Photonic Crystals and Plasmonics (META Toyama, 2024)

[9] Session organizer for conference session “Artificial EM materials,” 2024 IEEE International Conference on Computational Electromagnetics (ICCEM Nanjing, 2024)

[8] Organizing committee member (Registration Chair & Conference Treasurer) for 2024 IEEE International Conference on Computational Electromagnetics (ICCEM Nanjing, 2024)

[7] Session organizer for conference session “Time-modulating metamaterials and time-varying systems,” 2024 Photonics and Electromagnetics Research Symposium (PIERS Chengdu, 2024)

[6] 中国电子学会会员，2023-2024

[5] Session organizer for conference session “Integrated electrically-driven nano-photonic devices,” 2023 Photonics and Electromagnetics Research Symposium (PIERS Prague, 2023)

[4] Guest editor for special issue “Controlling electromagnetics in the nanoscale,” Frontiers in Physics, 2023

[3] President of Optical Socitey of America (OSA), Chapter of Nanyang Technological University, 2018-2020

[2] Vice President of Optical Socitey of America (OSA), Chapter of Nanyang Technological University, 2017-2018

[1] Vice President of IEEE Photonics Society Singapore Chapter, 2018-2019

科研项目

[14] 胡昊（项目负责人）, 罗宇, 李茁等，“瞬态光学国际联合实验室,” 国际合作联合实验室培育项目（重点项目）, 校级, 纵向, 2025-2026

[13] 胡昊（项目负责人）,  江苏省双创项目, 省级, 横向, 2025-2027 

[12] 胡昊（课题负责人）, “基于强非线性效应的*******芯片——*****光放大器,” JWKJW **项目重点项目, 国家级, 纵向, 2025-2027 

[11] 胡昊（项目负责人）, “时空光子晶体宽带非互易光放大机制及应用研究,” 国家自然科学基金青年项目, 国家级, 纵向, 2025-2027 

[10] 胡昊（项目负责人）, 刘亮亮, “基于超构材料的自由电子太赫兹辐射特性及其调控机理研究,” 江苏省自然科学基金青年项目, 省级, 纵向, 2024-2026

[9] 罗宇, 潘时龙, 李茁, 胡昊（项目参与人）等，“量子超材料学科创新引智基地,” 学科创新引智基地培育项目, 校级, 纵向, 2024-2025

[8] 胡昊 （项目负责人）, 刘亮亮, “时空光子晶体的光放大特性及其调控机理研究,” 基本科研业务费项目（青年科技创新基金项目理工类）, 校级, 纵向, 2024-2025

[7] 侯松岩 ,  胡昊（项目参与人）, “薄膜铌酸锂双微腔电光调制器的相位调控研究,” 雷达成像与微波光子技术教育部重点实验室开放基金, 校级, 纵向, 2024-2026

[6] 罗宇,  刘亮亮,  胡昊（项目参与人）等, “非厄米拓扑集成****技术,”  JWKJW重点实验室项目, 国家级,  纵向, 2024-2025

[5] 胡昊（项目负责人）, “适用于毫米波/太赫兹光子芯片的高性能自由电子片上光源,” 国家重大人才工程A类青年项目, 国家级, 纵向, 2023-2026

[4] 胡昊（项目负责人）, “适用于毫米波/太赫兹光子芯片的高性能自由电子片上光源,” 江苏省特聘教授项目, 省级, 纵向, 2023-2026

[3] 胡昊（项目负责人）, “紧凑型量子表面等离子体传感器,” 111引智基地建设科研项目国际学术骨干储备项目, 校级, 纵向, 2023-2024

[2] 胡昊（项目负责人）, “时变材料的基本原理及应用研究,” 南京市人社局留学人员科技创新项目择优资助（C类资助）, 市级, 纵向, 2023-2024

[1] 胡昊（项目负责人）, “时变材料的基本原理及应用研究,” 南京航空航天大学启动基金, 校级, 纵向, 2023-2024

教学与课程

[1] 2024年-至今，电子信息工程专业0424008班班主任

[2] 2025年-至今，现代半导体光电子学 (Modern Semiconductor Photonics and Electronics) [电子信息工程学院研究生课程；中文教学；32/32学时]

[3] 2024年-2025年，半导体光电子学 (Semiconductor Photonics and Electronics) [电子信息工程学院本科生专业选修课程；中文教学；24/24学时]

[4] 2023年-至今，电磁仿真与微波电路计算机辅助设计 (Computer Aided Design for Electromagnetic Simulation and Microwave Circuit) [国际教育学院本科生素质拓展选修课程；英文教学；24/24学时]

[5] 2025年-至今，传感器的原理及应用(Principle and Application of Sensor)  [电子信息工程学院本科生专业选修课程；中文教学；32/32学时]

团队成员

团队现有硕士生6名，博士生6名:

2025级 杨山奇 （博士生; 青岛大学硕士; 方向：拓扑光学）

2025级 马江南 （共同导师:罗宇；博士生; 广西科技大学硕士; 方向：光子晶体）

2025级 谢菁英 （共同导师:朱松；硕士生; 南京航空航天大学本科; 方向：光子晶体）

2024级 余尤秀 （博士生; 苏州大学硕士; 方向：时空超材料）

2024级 谢志雄 （博士生; 福建师范大学硕士；方向: 自由电子太赫兹辐射）

2024级 杜奕儒 （硕士生; 中国石油大学本科；方向: 拓扑光学）

2024级 陈杰冉 （硕士生; 杭州电子科技大学本科；方向: 非局域光学）

2024级 陈欣然 （共同导师:黄振宇；硕士生; 中国石油大学本科；方向: 计算电磁学）

2024级 倪德民 （共同导师:罗宇；硕士生;  南京理工大学紫金学院本科；方向: 表面波）

2024级 董   燕 （共同导师:李茁；硕士生; 武汉理工大学；方向:  合成维度）

2023级 杨玉坤 （共同导师:李茁；博士生；南京航空航天硕士; 方向：时变传输线、时域拓扑）

2023级 姜俊凯 （共同导师:李茁；直博生；南京航空航天本科; 方向：时间光子晶体、非厄米光学）

（实验室成员合影--摄于2025年6月5日南京紫金山）

招聘

团队经费充足，研究方向前沿，学术氛围浓厚，国际合作广泛，尊重想法创意，以培养高层次创新型人才为主要目标。每年拟招收1-2名优秀学生攻读博士和1-3名优秀学生攻读硕士，并长期招聘博士后，欢迎有学术抱负的学生加入。其中满足以下条件若干或之一的将优先考虑：

1）良好的数理基础和编程能力

2）优异的英语表达和写作能力

3）凝聚态物理/高能物理/固体物理/量子光学方向的学科背景

4）微波/太赫兹波/电路实验经验

同时也欢迎积极主动的本科生参与科研训练与毕业设计，有机会发表高质量论文。

如有意向，请联系胡昊老师：

申请硕士项目，请发送简历和本科成绩单；

申请博士/博后项目，请发送简历和研究提案（简要描述拟开展的研究方向的背景、意义和计划，及研究基础）。

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联系方式

电子邮箱：hao.hu@nuaa.edu.cn

办公室：南京航空航天大学将军路校区电子信息工程学院楼434室

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相关链接

Google Scholar: https://scholar.google.com/citations?user=u7MizUMAAAAJ&hl=zh-CN

课题组主页: http://www.nuaa-meta.cn/

长期合作学者：

罗宇 (南京航空航天大学);张柏乐 (新加坡南洋理工大学);王岐杰 (新加坡南洋理工大学);Francisco J. Garcia-Vidal (马德里自治大学);Ido Kaminer (以色列理工大学);林晓 (浙江大学);杨怡豪 (浙江大学); 李茁 (南京航空航天大学); 刘亮亮 (南京航空航天大学); 高东梁 (苏州大学); 侯松岩 (西安电子科技大学); 熊江(中国电子科技大学); 龙洋 (同济大学)

（国际联合实验室成员合影--摄于2025年3月17日南京航空航天大学电子信息工程学院）

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Selected Publications

† co-first author， *corresponding author

[15] Yukun Yang^†, Hao Hu^†,*, Liangliang Liu^†, Yihao Yang, Youxiu Yu, Yang Long, Xuezhi Zheng, Yu Luo*, Zhuo Li*, and Francisco J. Garcia-Vidal, “Topologically protected edge states in time photonic crystals with chiral symmetry,” ACS Photonics 12(5), 2389-2396 (2025). [期刊封面；两江科技、非线性光学快车等报道]

[14] Youxiu Yu, Dongliang Gao^*, Yukun Yang, Liangliang Liu, Zhuo Li, Qianru Yang, Haotian Wu, Linyang Zou, Xiao Lin, Jiang Xiong, Songyan Hou, Lei Gao^*, and Hao Hu^*, “Generalized coherent wave control at dynamic interfaces,” Laser & Photonics Reviews 19(4), 2400399 (2025). [两江科技等报道]

[13] Hao Hu^*, Xiao Lin, Guangwei Hu, Francisco J. Garcia-Vidal, and Yu Luo^*, “Enhanced Cherenkov radiation in twisted hyperbolic Van der Waals crystals,” InfoScience 2(1), e12424  (2025).

[12] Yaoran Zhang^†, Hao Hu^†, F. J. García-Vidal, Jingjing Zhang, Liangliang Liu^*, Yu Luo^*, and Zhuo Li^*, “Reconfigurable exceptional point-based sensing with 0.001-lambda sensitivity using spoof localized surface plasmons,” Advanced Photonics Nexus 3(5), 056004  (2024). [SPIE News、Phys.org、EurekAlert!、Statnano等报道]

[11] Youxiu Yu, Hao Hu*, Linyang Zou, Qianru Yang, Xiao Lin, Zhuo Li, Gao Lei*, and Dongliang Gao*, “Antireflection spatiotemporal metamaterials,” Laser & Photonics Reviews 17(9), 2300130 (2023) . [期刊封底；两江科技等报道]

[10] Haotian Wu^†, Hao Hu^†, Xixi Wang, Zhixia Xu, Baile Zhang^*, Qi Jie Wang^*, Yuanjin Zheng, Jingjing Zhang, Tie Jun Cui^*, and Yu Luo^*, “Higher‐order Topological States in Thermal Diffusion,” Advanced Materials 35(14), 2210825(2023). [化学与材料科学等报道]

[9] Yuval Adiv^†, Hao Hu^†, Shai Tsesses^†, Raphael Dahan, Kangpeng Wang, Yaniv Kurman, Alexey Gorlach, Hongsheng Chen, Xiao Lin, Guy Bartal, and Ido Kaminer^*, “Observation of 2D Cherenkov radiation,” Physical Review X 13(1), 011002 (2023). [两江科技等报道]

[8] Hao Hu^†, Song Han^†, Yang Hang^†,*, Dongjue Liu, Haoran Xue, Guigeng Liu, Zheyu Cheng, Qi Jie Wang, Shuang Zhang, Baile Zhang^*, and Yu Luo^*, “Observation of topological edge states in thermal diffusion,” Advanced Materials 34(31), 2202257 (2022). [化学与材料科学等报道]

[7] Hao Hu^†, Xiao Lin^†,*, Dongjue Liu, Hongsheng Chen, Baile Zhang^*, and Yu Luo^*, “Broadband enhancement of Cherenkov radiation using dispersionless plasmons,” Advanced Science 9(26), 2200538 (2022). [Advanced Science News报道]

[6] Hao Hu†, Xiao Lin†, Liang Jie Wong, Qianru Yang, Dongjue Liu, Baile Zhang*, and Yu Luo*, “Surface Dyakonov-Cherenkov Radiation,” eLight，2，2 (2022). [期刊特色论文；前苏联知名物理学家、迪亚克诺夫表面波发现者和命名者迪亚克诺夫教授以 "From Dyakonov-Cherenkov radiation to Dyakonov surface optics"为题，在《Light: Science & Applications》 撰写News & Views; Phys.org、EureAlert!、中国光学等报道]

[5] Xiao Lin†, Hao Hu†, Sajan Easo, Yi Yang, Yichen Shen, Kezhen Yin, Michele Piero Blago, Ido Kaminer*, Baile Zhang*, Hongsheng Chen, John Joannopoulos, Marin Soljacic, and Yu Luo*, “A Brewster route to Cherenkov detectors,” Nature Communications 12, 5554 (2021).

[4] Hao Hu, Xiao Lin*, Jingjing Zhang, Dongjue Liu, Patrice Genevet, Baile Zhang* and Yu Luo*, “Nonlocality induced Cherenkov threshold,” Laser & Photonics Reviews 14(10)，2000149 (2020).

[3] Hao Hu, Dongliang Gao, Xiao Lin, Songyan Hou, Baile Zhang, Qi Jie Wang* and Yuo Luo*, “Directing Cherenkov photons with spatial nonlocality,” Nanophotonics 9(10), 3435-3443 (2020).

[2] Hao Hu, Liangliang Liu*, Xiao Hu, Dongjue Liu, and Dongliang Gao*, “Routing emission with a multi-channel nonreciprocal waveguide,” Photonics Research 7(6), 642-646 (2019).

[1] Hao Hu, Jingjing Zhang, Stefan A Maier, and Yu Luo*, “Enhancing third-harmonic generation with spatial nonlocality,” ACS Photonics 5(2), 592-598 (2018).

Full Publications

2025

[54] Yukun Yang^†, Hao Hu^†,*, Liangliang Liu^†, Yihao Yang, Youxiu Yu, Yang Long, Xuezhi Zheng, Yu Luo*, Zhuo Li*, and Francisco J. Garcia-Vidal, “Topologically protected edge states in time photonic crystals with chiral symmetry,” ACS Photonics  12(5), 2389-2396 (2025). 

[53] Youxiu Yu, Dongliang Gao^*, Yukun Yang, Liangliang Liu, Zhuo Li, Qianru Yang, Haotian Wu, Linyang Zou, Xiao Lin, Jiang Xiong, Songyan Hou, Lei Gao^*, and Hao Hu^*, “Generalized coherent wave control at dynamic interfaces,” Laser & Photonics Reviews 19(4), 2400399 (2025). 

[52] Hao Hu^*, Xiao Lin, Guangwei Hu, Francisco J. Garcia-Vidal, and Yu Luo^*, “Enhanced Cherenkov radiation in twisted hyperbolic Van der Waals crystals,” InfoScience 2(1), e12424  (2025).

[51] Junkai Jiang^†, Hao Hu^†,*, Yang Long, Liangliang Liu, Songyan Hou, Dongjue Liu^* and Zhuo Li^*, “Broadband temporal localization and delocalized temporal edge states in time photonic crystal,” (2025). [under review]

[50] Dongjue Liu, Zeng Yang, Zhiyong Huang, Xinyi He, Songyan Hou, Biao Wang, Liangliang Liu, Song Zhu, Yi Liao^*, and Hao Hu^*, “Topological Edge States Induced by Strained Graphene,” (2025).  [under review]

[49] Hongyi Li^*, Haobin Hu, Zixiang Zhou, Jindi Huang, Fubeng Wang, Hao Hu^*, Zhuo Li^*, and Liangliang Liu^*, “Highly compact and robust filters enabled by effective localized surface plasmonic resonance,” Journal of Physics D: Applied Physics 58(18), 185106 (2025).

[48] Haotian Wu^†, Linyang Zou^†, Hao Hu, Qianru Yang, Yueqian Zhang, Tie Jun Cui^*, Guangwei Hu^*, and Yu Luo^*, “Electromagnetic Wave Trapping at the Discretized Interluminal Interface,” (2025). [under review]

[47] Siming Li^†, Haotian Wu^†, Jingjing Zhang, Rimi Banerjee, Linyang Zou, Yueqian Zhang, Hao Hu, Yidong Chong*, Qi Jie Wang*, and Yu Luo*, “Topological thermal crystalline insulators,” (2025). [under review]

[46] Yaoran Zhang, Jian Ling, Yuying Jiang, Zhepeng Fu, Hao Hu, Liangliang Liu*, Yu Luo*, and Zhuo Li*, “A compact reconfigurable orbital angular momentum antenna based on a single spoof localized surface plasmonic resonator,” IEEE Transactions on Antennas and Propagation (2025).

[45] Linyang Zou, Hao Hu, Haotian Wu, Yang Long, Yidong Chong, Baile Zhang*, and Yu Luo*, “Momentum flatband and superluminal propagation in a photonic time Moir´e superlattice,” (2025). [under review]

[44] Qianru Yang, Haotian Wu, Hao Hu, Linyang Zou, F. J. García-Vidal, Guangwei Hu*, and Yu Luo*, “Spatiotemporal superfocusing,”  Laser & Photonics Reviews 2500126 (2025).

[43] Hongyi Li, Lingyun Niu, Liangliang Liu^*, Lepeng Zhang, Hao Hu, Haochi Zhang, Yu Luo, and Zhuo Li^*, “Miniaturized diplexer with high selectivity based on transition-free effective surface plasmon polaritons,” (2025). [under review]

[42] Songyan Hou^*, Hao Hu, Chengyi Zhu, Mengfang Xu, Jiajun Zhang, Haoxuan Xiao, Zhihong Liu, Weichuan Xing, Shuzhen You, Baiquan Liu, Yiping Zhang, Junhong Yu*, Zhenwei Xie, JinCheng Zhang*, and Yue Hao, “Engineering quantum emitters in 2D materials,” Advanced Optical Materials (2025). [accepted]

[41] Hongyi Li, Ling Jian, Liangliang Liu^*, Lingyun Niu, Lepeng Zhang, Jindi Huang, Haochi Zhang, Dongjue Liu, Hao Hu, Yu Luo^*, and Zhuo Li^*,  “Ultra-wideband and minituarized waveguide band-pass filter based on effective surface plasmon polaritons,” Physical Review Applied 23, 034061 (2025).

[40] Songyan Hou^*, Zhenwei Xie, Chengyi Zhu, Haoxuan Xiao, Jiajun Zhang, Mengfang Xu, Xianhe Liu, Xiaoning He, Hao Hu, Zhihong Liu, Weichuan Xing, Jincheng Zhang^*, Shuzhen You^*, and Yue Hao,  “Improved selectivity in dry etching of lithium niobate with thermal annealed hydrogen silsesquioxane mask,” (2025). [under review]

2024

[39] Songyan Hou^*, Hao Hu^*, Zhihong Liu, Weichuan Xing, and Jincheng Zhang^*, “Broadband transmissive polarization rotator by gradiently-twisted α-MoO₃,” Applied Physics Letters 124(11), 111107 (2024).

[38] Xinhua Li, Liangliang Liu*, Yaoran Zhang, Yue Feng, Guodong Han, Helin Yang, Hao Hu*, Yu Luo, and Zhuo Li*, “Hybridization of localized spoof plasmonic skyrmions and its application in micro-displacement sensing,” Advanced Optical Materials 12(13), 2302744 (2024).

[37] Yaoran Zhang^†, Hao Hu^†, F. J. García-Vidal, Jingjing Zhang, Liangliang Liu^*, Yu Luo^*, and Zhuo Li^*, “Reconfigurable exceptional point-based sensing with 0.001-lambda sensitivity using spoof localized surface plasmons,” Advanced Photonics Nexus 3(5), 056004  (2024). 

[36] Songyan Hou^†,*, Hao Hu^†, Zhihong Liu, Weichuan Xing, Jincheng Zhang^*, and Yue Hao, “Tunable double notch filter on thin-film lithium niobate platform,” Optics Letters 61(6), 1022-1024 (2024). 

[35] Songyan Hou^*, Hao Hu, Zhihong Liu, Weichuan Xing, Jincheng Zhang^*, and Yue Hao, “High-speed electro-optic modulators based on thin-film lithium niobate,” Nanomaterials 14(10), 867 (2024).

[34] Yang Long^∗, Linyang Zou, Letian Yu, Hao Hu, Jiang Xiong, and Baile Zhang^∗, “Inverse design of photonic topological time crystal via deep learning,” Optical Materials Express 14(8), 2032-2039 (2024).

[33] Haotian Wu, Qianru Yang, Hao Hu, Linyang Zou,  Xixi Wang,  Jijun He, Shilong Pan, Yuanjin Zheng^* Tie Jun Cui^*, and Yu Luo^*, “Conformal spatiotemporal modulation enabled geometric frequency combs,” ACS Photonics 11(8), 2992–3002  (2024). 

[32] Chan Wang, Xuhuinan Chen, Zheng Gong, Ruoxi Chen, Hao Hu, Huaping Wang*, Yi Yang, Low Tony, Baile Zhang, Hongsheng Chen, and Xiao Lin^*, “Superscattering of light: fundamentals and applications,” Reports on Progress in Physics 87, 126401 (2024). 

[31] Yuhan Zhong, Chan Wang, Chenxu Bian, Xuhuinan Chen, Jialin Chen, Xingjian Zhu, Hao Hu, Tony Low, Siyuan Dai, Hongsheng Chen*, Baile Zhang, and Xiao Lin^*, “Near-field directionality governed by asymmetric dipole–matter interactions,” Optics Letters 49(4), 826-829 (2024).

2023

[30] Youxiu Yu, Hao Hu^*, Linyang Zou, Qianru Yang, Xiao Lin, Zhuo Li, Gao Lei*, and Dongliang Gao*,“Antireflection spatiotemporal metamaterials,” Laser & Photonics Reviews 17(9), 2300130 (2023).

[29] Haotian Wu^†, Hao Hu^†, Xixi Wang, Zhixia Xu, Baile Zhang*, Qi Jie Wang^*, Yuanjin Zheng, Jingjing Zhang, Tie Jun Cui^*, and Yu Luo^*, “Higher‐order Topological States in Thermal Diffusion,” Advanced Materials 35(14), 2210825 (2023).

[28] Yuval Adiv^†, Hao Hu^†, Shai Tsesses^†, Raphael Dahan, Kangpeng Wang, Yaniv Kurman, Alexey Gorlach, Hongsheng Chen, Xiao Lin, Guy Bartal, and Ido Kaminer^*, “Observation of 2D Cherenkov radiation,” Physical Review X 13, 011002 (2023).

[27] Dongjue Liu, Hao Hu^*, and Jingjing Zhang*, “Edge states in coupled non-Hermitian resonators,” Optics Letters 127(11), 043904(2023).

[26] Songyan Hou*, Hao Hu^†, Weichuan Xing, Zhihong Liu, Jincheng Zhang*, and Yue Hao, “Improving linewidth and extinction ratio performances of lithium niobate ring modulator using ring-pair structure,” Advanced Photonics Research 4(8), 2300169 (2023).

[25] Dongjue Liu^†, Zihao Wang^†, Zheyu Cheng, Hao Hu, Qijie Wang, Haoran Xue*, Baile Zhang*, and Yu Luo*, “Simultaneous manipulation of line‐gap and point‐gap topologies in non‐hermitian lattices,” Laser & Photonics Reviews 17(8), 2200371 (2023).

[24] Zheng Gong, JIalin Chen, Ruoxi Chen, Xingjian Zhu, Chan Wang, Xinyan Zhang, Hao Hu, Yi Yang, Baile Zhang*, Hongsheng Chen*, Ido Kaminer, and Xiao Lin*, “Interfacial Cherenkov radiation with ultralow-energy electrons,” Proceedings of the National Academy of Science 120(38), e2306601120 (2023).

[23] Shuaijie Yuan, Xinxing Zhou*, Yu Chen, Yuhan Zhong, Lijuan Sheng, Hao Hu, Hongsheng Chen*, Ido Kaminer, and Xiao Lin*, “Breakdown of effective-medium theory by a photonic spin Hall effect,” Science China Physics, Mechanics & Astronomy 66, 114212 (2023).

[22] Jialin Chen, Ruoxi Chen, Zheng Gong, Hao Hu, Yi Yang, Xinyan Zhang, Chan Wang, Ido Kaminer, Hongsheng Chen*, Baile Zhang*, and Xiao Lin*, “Low-velocity-favored transition radiation,” Physical Review Letters 131, 113002 (2023).

 

2022

[21] Hao Hu^†, Song Han^†, Yang Hang^†,*, Dongjue Liu, Haoran Xue, Guigeng Liu, Zheyu Cheng, Qi Jie Wang, Shuang Zhang, Baile Zhang*, and Yu Luo*, “Observation of topological edge states in thermal diffusion,” Advanced Materials 34(31), 2202257 (2022).

[20] Hao Hu^†, Xiao Lin^†,*, Dongjue Liu, Hongsheng Chen, Baile Zhang*, and Yu Luo*, “Broadband enhancement of Cherenkov radiation using dispersionless plasmons,” Advanced Science 9(26), 2200538 (2022).

[19] Hao Hu^†, Xiao Lin^†, Liang Jie Wong, Qianru Yang, Dongjue Liu, Baile Zhang*, and Yu Luo*, “Surface Dyakonov-Cherenkov radiation,” eLight 2, 2 (2022).

[18] Helin Yang, Kwok-Yan Lam*, Liang Xiao, Zehui Xiong, Hao Hu, Dusit Niyato, and H Vincent Poor，“Lead federated neuromorphic learning for wireless edge artificial intelligence,” Nature Communications 13, 4269 (2022).

[17] Qianru Yang, Hao Hu, Xiaofeng Li, and Yu Luo*，“Cascaded parametric amplification based on spatiotemporal modulations,” Photonics Research 11(5), B125-B135 (2022).

[16] Fei Yan, Qi Li, Hao Hu, Ze Wen Wang, Hao Tian, Li Li*, Yu Luo*, Qi Jie Wang*, “Terahertz high-Q magnetic dipole resonance induced by coherent Fano interactions,”  Applied Physics Letters 121(20), 201704 (2022).

2021

[15] Xiao Lin^†, Hao Hu^†, Sajan Easo, Yi Yang, Yichen Shen, Kezhen Yin, Michele Piero Blago, Ido Kaminer*, Baile Zhang*, Hongsheng Chen, John Joannopoulos, Marin Soljacic, and Yu Luo*, “A Brewster route to Cherenkov detectors,”  Nature Communications 12, 5554 (2021).

[14] Hao Hu, Xiao Lin, and Yu Luo*. “Free-electron radiation engineering via structured environment,” Progress in Electromagnetics Research 171, 75-88 (2021).

[13] Liqiao Jing, Xiao Lin, Zuojia Wang*, Ido Kaminer*, Hao Hu, Erping Li, Yongmin Liu, Min Chen, Baile Zhang, Hongsheng Chen*, “Polarization shaping of free‐electron radiation by gradient bianisotropic metasurfaces,” Laser & Photonics Reviews 15(4), 2000426 (2021).

 

2020

[12] Hao Hu, Xiao Lin*, Jingjing Zhang, Dongjue Liu, Patrice Genevet, Baile Zhang* and Yu Luo*,“Nonlocality induced Cherenkov threshold,” Laser & Photonics Reviews 14(10)，2000149 (2020).

[11] Hao Hu, Dongliang Gao, Xiao Lin, Songyan Hou, Baile Zhang, Qi Jie Wang* and Yuo Luo*, “Directing Cherenkov photons with spatial nonlocality,” Nanophotonics 9(10), 3435-3443 (2020).

[10] Xinyan Zhang, Hao Hu, Xiao Lin*, Lian Shen, Baile Zhang, Hongsheng Chen*, “Confined transverse-electric graphene plasmons in negative refractive-index systems, " npj 2D Materials and Applications 4, 25 (2020).

[9] Yanqiu Wang, Hao Hu, Qin Zhang, Dong Liang Gao*, and Lei Gao*, “Topologically-tuned spin Hall shift around Fano resonance,” Optics Express 28(15), 21641-21649 (2020).

[8] Chan Wang, Chao Qian, Hao Hu, Lian Shen, Zuo Jia Wang, Huaping Wang, Zhiwei Xu, Baile Zhang, Hongsheng Chen, Xiao Lin*, “Superscattering of light in refractive-index near-zero environments,” Progress in Electromagnetics Research 168, 15-23 (2020).

 

2019

[7] Hao Hu, Liangliang Liu*, Xiao Hu, Dongjue Liu, and Dongliang Gao*, “Routing emission with a multi-channel nonreciprocal waveguide,” Photonics Research 7(6), 642-646 (2019).

[6] Hao Hu, Xiao Lin, Dongjue Liu, Patrice Genevet, Baile Zhang, Yu Luo*, “Revisit Cherenkov Radiation in the Hyperbolic Metamaterials,” Photonics & Electromagnetics Research Symposium-Fall (PIERS-Fall) 318-324 (2019).

[5] Wangcheng Lin, Yanqiu Wang, Hao Hu, Dongjue Liu, Dongliang Gao*, and Lei Gao*, “Reconfigurable sensor and nanoantenna by graphene-tuned Fano resonance,” Optics Express 27(24), 35925-35934 (2019).

[4] Dongjue Liu, Yao Huang, Hao Hu, Liangliang Liu, Dongliang Gao, Lixin Ran, Dexin Ye*, and Yu Luo*, “Designing spatial Kramers–Kronig media using transformation optics,” IEEE Transactions on Antennas and Propagation 68(4), 2945-2949 (2019).

[3] Ran Shi, Dong Liang Gao*, Hao Hu, Yanqiu Wang, Lei Gao*, “Enhanced broadband spin Hall effects by core-shell nanoparticles,” Optics Express 27(4), 4808-4817 (2019).

 

2016-2018

[2] Hao Hu, Jingjing Zhang, Stefan A Maier, and Yu Luo*, “Enhancing third-harmonic generation with spatial nonlocality,” ACS Photonics 5(2), 592-598 (2018).

[1] Jinxi Huang^†, Hao Hu^†, Zhewei Wang, Wenyuan Li, Ji Cang, Jianqi Shen, Hui Ye*, “Analysis of light-emission enhancement of low-efficiency quantum dots by plasmonic nano-particle,” Optics Express 24(8), 8555-8573 (2016).

Conference Papers

[14] Hao Hu,  “Topological time photonic crystals,” International Applied Computational Electromagnetics Society Symposium, Huangshan, China, 8-11 August 2025 (Invited Talk).

[13] 胡昊,  “拓扑时变光子晶体,” 第4届全国超材料大会, 深圳, 中国, 2025年5月15日-18日（特邀报告）.

[12] 胡昊,  “自由电子辐射的超构材料调控机理及应用,” 第39届南京地区研究生通信年会, 南京, 中国, 2024年12月24日 （特邀报告）.

[11] Hao Hu,  “Time edge states protected by chiral symmetry,” International Conference on Metamaterials, Photonic Crystals and Plasmonics, Toyama, Japan, 16-19 July 2024.

[10] Hao Hu,  “Cherenkov radiation in twisted α-MoO3 Slab,” Progress in Electromagnetics Research Symposium, Chengdu, China, 21-25 April 2024.

[9] Hao Hu, “Free-electron light source based on twisted α-MoO3 slab,” IEEE International Conference on Computational Electromagnetics, Nanjing, China, 15-17 April 2024.

[8] Hao Hu,  “Experimental realization of topological edge states in pure diffusion systems,” Progress in Electromagnetics Research Symposium, Prague, Czech Republic, 3-6 July 2023.

[7] Hao Hu,  “Experimental realization of thermal topological edge states,” International Conference on Thermodynamics and Thermal Metamaterials, Shanghai, China. 17-19 August 2022.

[6] Hao Hu,  “Revisit Cherenkov radiation in the hyperbolic metamaterials,” Progress in Electromagnetics Research Symposium, Xiamen, China, 17-20 December 2019.

[5] Hao Hu, Xiao Lin, Dongjue Liu, Patrice Genevet, Baile Zhang, and Yu Luo, “Probe the ultimate nonlocal limit of 'threshold-free' Cherenkov radiation,” Conference on Lasers and Electro-Optics, San Jose, USA, 5-10 May 2019.

[4] Hao Hu, “Nonlocal limit of Cherenkov radiation in hyperbolic metamaterials,” Global Congress and Expo on advancements of Laser optics and photonics, Valencia, Spain, 25-27 March 2019.

[3] Hao Hu,  “Enhancing optical nonlinearity using quantum nonlocal effect,” Progress in Electromagnetics Research Symposium, Tokyo, Japan, 1-4 August 2018.

[2] Hao Hu, “Enhancing optical nonlinearity using special nonlocality,” Advances in Quantum Enginnering International Meeting, Singapore, 25-27 June 2018.
[1] Hao Hu, and Yu Luo, “Third harmonic generation enhanced by nonlocal effect,” Conference on Lasers and Electro-Optics (Pacific Rim), Singapore, 31 July - 4 August 2017.

Patents

[2] 高雷,余尤秀,胡昊,高栋梁, “一种基于时空减反膜及抗反射系统,” 国家发明专利, 专利号：ZL202310321458.6, 专利申请日: 2023.03.29, 授权公告日: 2025.02.07.

[1] 高雷,余尤秀,胡昊,高栋梁, “一种基于时空相干波调控的波形调制方法,” 国家发明专利, 专利号：ZL202410019512.6, 专利申请日: 2024.01.05, 授权公告日: 2024.08.20.

Thesis

[1] Hao Hu, ''Manipulating Cherenkov radiation by artificial structures'' [Doctoral dissertation, Nanyang Technological University], Digital Repository of Nanyang Technological University, 2020.