个人简历
学习经历: |
1993/09-1997/07 |
武汉大学物理学院 |
学士 |
1997/09-2000/07 2000/09-2006/06 |
中科院上海应用物理所 宾夕法尼亚州立大学 |
硕士,导师:李民乾教授 博士,导师:Peter Eklund教授 |
工作经历: |
2006/06-2009/06 |
哈佛大学 |
博士后,合作导师:Charles Lieber教授 |
2009/06-2014/03 |
新加坡南洋理工大学物理与应用物理系 |
南洋助理教授,NRF Fellow |
2014/03-2016/08 |
新加坡南洋理工大学物理与应用物理系 |
南洋副教授 |
2016/08-2021/01 2021/02-至今 |
新加坡南洋理工大学物理与应用物理系 清华大学物理系 |
教授 教授 |
教学
《基础物理II》、《能源物理》、《光学、振动和波》和《电磁学》
研究领域
熊教授的研究背景是凝聚态光谱学和超快光谱学,主要关注低维量子材料因为尺度和维度而引起的量子局限效及其产生的新奇物理性质、微腔增强光-物质相互作用、以及光子学和光电子学器件。
1. 半导体微腔光-物质强耦合相互作用、激子极化激元BEC和激射以及非平衡态动力学;
2. 钙钛矿半导体激子精细结构、微腔激子极化激元人工晶格、非线性动力学和激子极化激元器件;
3. 二维层状材料及范德华异质结的载流子超快动力学、电荷和能量传递的动力学;
4. 新型二维材料及范德华异质结的光子学和光电子学器件。
职业生涯中共指导和毕业了20位博士研究生,和50多位博士后研究人员(包括访问学者),其中50多位目前在美国、英国、比利时、印度及内地各高校及研究所任教职。目前在清华指导12位博士研究生。计划每年招收2名博士研究生,常年招聘博士后,欢迎感兴趣的同学联系我!
奖励、荣誉和学术兼职
奖励、荣誉:
2024 IUMRS Mid-Career Researcher Award
2023 微腔光学成就奖 (Microcavity Achievement Award)
2022 美国材料研究学会会士
2021 美国光学会会士
2019 亚太材料科学院院士
2018 美国物理学会会士
2019-2023 科睿唯安世界高引科学家(交叉领域)
2017 国家特聘专家长期项目获得者
2015 新加坡物理学会纳米科技奖
2014 新加坡国家研究基金会首批NRF Investigator奖
2014 新加坡南洋理工大学研究卓越奖
2009 新加坡国家研究基金会第二批NRF Fellow奖
学术兼职:
2021-至今 《物理学报》和《Chinese Physics B》副主编
2020-至今 《Nano Letters》副主编和《半导体学报》副主编
2018-至今 《ACS Photonics》、《Nano Research》、《Science China Materials》、《eScience》、《National Science Open》、《Science Bulletin》等杂志国际编委会编委
2018-2020 《Optics Express》副主编
主要论著(*为论文通讯作者)
在国际知名杂志上发表了330多篇文章,其中包括《Nature》4篇,《Nature Physics》、《Nature Review Physics》、《Nature Materials》、《Nature Photonics》、《Nature Nanotechnology》及《Nature Communications》等子刊30篇,《Science》1篇及《Science Advances》8篇),《Physical Review Letters》2篇,《Light Science & Applications》2篇,总引用次数超过30000次,H-因子97。科睿唯安交叉领域全球高被引科学家(2019-2023)。主持或参与编撰图书及章节5部,国际及中国专利授权9项。
部分代表性文章:
光-物质强耦合相互作用、激子极化激元玻色-爱因斯坦凝聚和激射:
1. Y. Luo#, Q.B. Guo#, X.Y. Deng, S. Ghosh, Q. Zhang, H.X. Xu*, and Qihua Xiong*, “Manipulating nonlinear exciton polaritons in an atomically-thin semiconductor with artificial potential landscapes”, Light: Sci. & Appl. 12, 220. DOI: 10.1038/s41377-023-01268-2 (2023)
2. Y.Z. Chen#, Y. Shi#, Y.S. Gan, H.Y. Liu, T.F. Li, S. Ghosh*, and Qihua Xiong*, “Unraveling the ultrafast coherent dynamics of exciton polariton propagation at room temperature”, Nano Lett. 23, 8704-8711 (2023)
3. J.P. Song, Q.Y. Shang, X.Y. Deng, L. Liang, C. Li, X.F. Liu, Qihua Xiong*, and Q. Zhang*, “Continuous-wave pumped perovskite lasers with device area below 1 mm2”, Adv. Mater. 35, 2302170. DOI: 10.1002/adma.202302170 (2023)
4. J.Q. Wu#, S. Ghosh#, Y.S. Gan, Y. Shi, S. Mansal, H.D. Sun, B.L. Zhang, T.C.H. Liew*, R. Su*, and Qihua Xiong*, “High-order topological polariton corner state lasing”, Science Advances 9, eadg432. DOI: 10.1126/sciadv.adg4322 (2023)
5. S. Zhang, Z.Y. Zhu, W.N. Du, X.X. Wu, S. Ghosh, Q. Zhang, Qihua Xiong, and X.F. Liu*, “All-optical control of rotational exciton polaritons condensate in perovskite microcavities”, ACS Nano DOI: 10.1021/acsphotonics.2c01869 (2023)
6. M.Y. Leng, J.Q. Wu, K. Dini, J. Liu, Z.H. Hu, J. Tang, T.C.H. Liew, H.D. Sun, R. Su*, and Qihua Xiong*, “Optically pumped polaritons in perovskite light-emitting diodes”, ACS Photonics, DOI: 10.1021/acsphotonics.2c01999 (2023)
7. J.X. Zhao, A. Fieramosca*, K. Dini, R.Q. Bao, W. Du, R. Su, Y. Luo, W.J. Zhao, D. Sanvitto, T.C.H. Liew* & Qihua Xiong* “Exciton polariton interactions in Van der Waals superlattices at room temperature”, Nature Communications 14, 1512, DOI: 10.1038/s41467-023-36912-3 (2023)
8. J. Wang*, Y.T. Peng, H.W. Xu, J.G. Feng, Y.Q. Huang, J.Q. Wu, T.C.H. Liew*, and Qihua Xiong*, “Controllable vortex lasing arrays in a geometrically frustrated exciton-polariton lattice at room temperature”, National Science Review 10 nwac096. DOI: 10.1093/nsr/nwac096 (2023)
9. S. Ghosh, R. Su*, J.X. Zhao, A. Fieramosca, J.Q. Wu, T.F. Li, Q. Zhang, F. Li, Z.H. Chen, T.C.H. Liew, D. Sanvitto, Qihua Xiong*, “Microcavity exciton polaritons at room temperature”, Photonics Insights 1, R04 (2022)
10. J.X. Zhao#, A. Fieramosca#,*, R.Q. Bao, W. Du, K. Dini, R. Su, J.G. Feng, Y. Luo, D. Sanvitto, T.C.H. Liew, and Qihua Xiong*, “Nonlinear polariton parametric emission in an atomically thin semiconductor based microcavity”, Nature Nanotechnol. 17, 396–402 (2022)
11. L. Zhang, J.Q. Hu, J.Q. Wu, R. Su, Z.H. Chen, Qihua Xiong, H. Deng*, “Recent developments on polariton lasers”, Progress in Quantum Electronics 83, 100399 (2022)
12. J.G. Feng#,*, Jun Wang#, A. Fieramosca#, R.Q. Bao, J.X. Zhao, R. Su, Y.T. Peng, T.C.H. Liew, D. Sanvitto, and Qihua Xiong*, “All-optical switching based on interacting exciton polaritons in self-assembled perovskite microwires”, Science Advances 7, eabj6627 (2021)
13. Rui Su*,#, Eliezer Estrecho*,#, D. Biegańska, Y.Q. Huang, M. Wurdack, M. Pieczarka, A.G. Truscott, T.C.H. Liew, E.A. Ostrovskaya* and Qihua Xiong*, “Direct measurement of a non-Hermitian topological invariant in a hybrid light-matter system”, Science Advances 7, abj8905 (2021)
14. J.Q. Wu, R. Su*, A. Fieramosca, S. Ghosh, J.X. Zhao, T.C.H. Liew*, and Qihua Xiong*, “Perovskite polariton parametric oscillator”, Adv. Photon. 3, 055003 (2021)
15. R. Su#, A. Fieramosca#, Q. Zhang, H.S. Nguyen, E. Deleporte, Z.H. Chen, D. Sanvitto*, T.C.H. Liew and Qihua Xiong*, “Perovskite semiconductors for room-temperature exciton-polaritonics”, Nature Materials, DOI: 10.1038/s41563-021-01035-x (perspectives) (2021)
16. R. Su*,#, S. Ghosh#, T.C.H. Liew*, and Qihua Xiong*, “Optical switching of topological phase in a perovskite polariton lattice”, Science Advances 7, eabf8049. DOI: 10.1126/sciadv.abf8049 (2021)
17. J.X. Zhao#, R. Su#, A. Fieramosca#, W.J. Zhao, W. Du, X. Liu, C. Diederichs, D. Sanvitto, T.C.H. Liew, and Qihua Xiong*, “Ultralow threshold polariton condensate in a monolayer semiconductor microcavity at room temperature”, Nano Lett. 21, 3331–3339. DOI: 10.1021/acs.nanolett.1c01162 (2021)
18. J.Q. Wu#, S. Ghosh#, R. Su*, A. Fieramosca, T.C.H. Liew*, and Qihua Xiong*, “Nonlinear parametric scattering of exciton polaritons in perovskite microcavities”, Nano Lett. 21, 3120–3126. DOI:10.1021/acs.nanolett.1c00283 (2021)
19. J. Wang#, H.W. Xu#, R. Su*, Y.T. Peng, J.Q. Wu, T. C. H. Liew*, and Qihua Xiong*, “Spontaneously coherent orbital coupling of counterrotating exciton polaritons in annular perovskite microcavities”, Light: Science and Applications 10, 45. DOI: 10.1038/s41377-021-00478-w (2021)
20. R. Su, S. Ghosh, J. Wang, S. Liu, C. Diederichs, T.C.H. Liew*, and Qihua Xiong*, “Observation of exciton polariton condensation in a perovskite lattice at room temperature”, Nature Physics 16, 301-306 (2020)
21. R. Su, J. Wang, J.X. Zhao, J. Xing, W.J. Zhao, C. Diederichs, T.C.H. Liew* and Qihua Xiong*, “Room temperature long-range coherent exciton polariton condensate flow in lead halide perovskites”, Science Advances 4, eaau0244, DOI: 10.1126/sciadv.aau0244 (2018)
22. J. Wang, R. Su, J. Xing, D. Bao, C. Diederichs, S. Liu, T.C.H. Liew, Z.H. Chen*, Qihua Xiong*, “Room temperature coherently coupled exciton polaritons in two-dimensional organic-inorganic perovskite”, ACS Nano 12, 8382-8389 (2018)
23. R. Su, C. Diederichs, J. Wang, T.C.H. Liew, J.X. Zhao, S. Liu, W. Xu, Z.H. Chen, and Qihua Xiong*, “Room-temperature polariton lasing in all-inorganic perovskite nanoplatelets”, Nano Lett. 17, 3982–3988 (2017)
二维磁性材料光谱学及准粒子动力学:
1. L.L. Hu, H.X. Wang, Y.Z. Chen, K. Xu, M.R. Li, H.Y. Liu, P. Gu, Y.B. Wang, M.D. Zhang, H. Yao*, and Qihua Xiong*, “Observation of a magnetic phase transition in monolayer NiPS3”, Phys. Rev. B 107, L220407 (2023) (letter)
2. C. Ye, C. Wang, Q. Wu, S. Liu, J.Y. Zhou, G.P. Wang, A. Söll, Z. Sofer, M. Yue, X. Liu*, M.L. Tian, Qihua Xiong*, W. Ji*, and X.R. Wang*, “Layer-Dependent Interlayer Antiferromagnetic Spin Reorientation in Air-Stable Semiconductor CrSBr”, ACS Nano, DOI: 10.1021/acsnano.2c01151 (2022)
3. A.J. Yang*, K. Han, K. Huang, C. Ye, W. Wen, R.X. Zhu, R. Zhu, J. Xu, T. Yu, P. Gao, Qihua Xiong, and R.X. Wang*, “Van der Waals integration of high-kappa perovskite oxides and two-dimensional semiconductors”, Nature Electron. 5, 233–240 (2022)
4. K. Lee, D.-K. Lee, D.S. Yang, R. Mishra, D.-J. Kim, S. Liu, Qihua Xiong, S.K. Kim, K.-J. Lee, and H.S. Yang*, “Superluminal-like magnon propagation in antiferromagnetic NiO at nanoscale distances”, Nature Nanotechnol. 16, 1337–1341. DOI: 10.1038/S41565-021-00983-4 (2021)
5. S. Liu, A. Granados del Aguila, D. Bhowmick, C.K. Gan, T. Thu Ha Do, M.A. Prosnikov, D. Sedmidubsky, Z. Sofer, P.C.M. Christianen, P. Sengupta*, and Qihua Xiong*, “Direct observation of magnon-phonon strong coupling in two-dimensional antiferromagnet at high magnetic fields”, Phys. Rev. Lett. 127, 097401, DOI: 10.1103/PhysRevLett.127.097401 (2021)
6. T.T. Yin#, K.A. Ajit Ulman#, S. Liu, A. Granados del Águila, Y.Q. Huang, L.F. Zhang, M. Serra, D. Sedmidubsky, Z. Sofer, S.Y. Quek*, and Qihua Xiong*, “Chiral phonons and giant magneto-optical effect in CrBr3 2D magnet”, Adv. Mater. 33, 2101618, DOI: 10.1002/ADMA.202101618 (2021)
7. S. Liu#, Y.Z. Wu#, X. Liu, A. Granados del Aguila, F.Y. Xuan, A. Chaturvedi, H. Zhang, S.Y. Quek*, and Qihua Xiong*, “Light-matter interactions in high quality manganese-doped two-dimensional molybdenum diselenide”, Sci. China. Mater. DOI:10.1007/s40843-020-1641-9 (2021)
8. X.Z. Wang, K.Z. Du, Y.Y. Liu, P. Hu, J. Zhang, Q. Zhang, M.H. Owen, X. Lu, C.K. Gan, P. Sengupta, C. Kloc and Qihua Xiong*, “Raman spectroscopy of atomically thin two-dimensional magnetic iron phosphorus trisulfide (FePS3) crystals”, 2D Materials 3, 031009 (2016)
9. K.Z. Du, X.Z. Wang, Y. Liu, P. Hu, M.I.B. Utama, C.K. Gan, Qihua Xiong* and C. Kloc*, “Weak Van der Waals stacking, wide-range band gap and Raman study on ultrathin layers of metal phosphorus trichalcogenides”, ACS Nano 10, 1738-1743 (2016)
低维半导体材料激子精细结构及其载流子动力学研究:
1. Y.B. Wang#, H.W. Xu#, X.Y. Deng, T.C.H. Liew, S. Ghosh*, and Qihua Xiong*, “Topological single-photon emission from quantum emitter chains”, npj Quantum information 10, 13. DOI: 10.1038/s41534-024-00807-y (2024)
2. A. Granados del Águila#,*, Y.R. Wong#, I. Wadgaonkar, A. Fieramosca, X. Liu, K. Vaklinova, S. Dal Forno, T. Thu Ha Do, H.Y.0 Wei, K. Watanabe, T. Taniguchi, K.S. Novoselov, M. Koperski, M. Battiato, and Qihua Xiong*, “Ultrafast exciton fluid flow in an atomically thin MoS2 semiconductor”, Nature Nanotechnol. 18, 1012–1019. DOI: 10.1038/s41565-023-01438-8 (2023)
3. M.-R. Amara, Z. Said, C.X. Huo, A. Pierret, C. Voisin, W.-B. Gao, Qihua Xiong, and C. Diederichs*, “Spectral fingerprint of quantum confinement in single CsPbBr3 nanocrystals”, Nano Lett. 23, 3607–3613 (2023)
4. Y.Q. Huang*, R. Su, Y.B. Wang, C. Zhu, J.G. Feng, J.X. Zhao, Z. Liu, and Qihua Xiong*, “A Fano cavity-photon interface for directional suppression of spectral diffusion of a single perovskite nanoplatelet”, Nano Lett. DOI 10.1021/acs.nanolett.2c03073 (2022)
5. E. Marcellina, X. Liu, Z.H. Hu, A. Fieramosca, Y.Q. Huang, W. Du, S. Liu, J.X. Zhao, K.J. Watanabe, T. Taniguchi, and Qihua Xiong*, “Evidence for Moiré trions in twisted MoSe2 homobilayers”, Nano Lett. 21, 4461–4468. DOI: 10.1021/acs.nanolett.1c01207 (2021)
6. W.J. Zhao, R. Su, Y.Q. Huang, J.Q. Wu, C.F. Fong, J.G. Feng, and Qihua Xiong*, “Transient circular dichroism and exciton spin dynamics in all-inorganic halide perovskites”, Nature Communications 11, 5665, DOI: 10.1038/s41467-020-19471-9 (2020)
7. S. Liu, A. Granados del Águila*, X. Liu, Y.H. Zhu, Y. Han, A. Chaturvedi, P. Gong, H.Y. Yu, H. Zhang, W. Yao, and Qihua Xiong*, “Room-temperature valley polarization in atomically thin semiconductors via chalcogenide alloying”, ACS Nano 14, 9873–9883 (2020)
8. T. Thu Ha Do, A. Granados del Águila, D. Zhang, J. Xing, S. Liu, M.A. Prosnikov, W.B. Gao, K. Chang, P.C.M. Christianen, and Qihua Xiong*, “Bright exciton fine-structure in two-dimensional lead halide perovskites”, Nano Lett. 20, 5141–5148 (2020)
9. J.X. Zhao, W.J. Zhao, W. Du, R. Su, and Qihua Xiong*, “Dynamics of exciton energy renormalization in monolayer transition metal disulfides”, Nano Research 13, 1399–1405 (2020)
10. C.X. Huo, C.F. Fong, M.-R Amara, Y.Q. Huang, B. Chen, H. Zhang, L.J. Guo, H.J. Li, W. Huang, C. Diederichs, and Qihua Xiong*, “Optical spectroscopy of single colloidal CsPbBr3 perovskite nanoplatelets”, Nano Lett. 20, 3673–3680 (2020)
11. S. Liu, S.S. Sun*, C.K. Gan*, A. Granados del Aguila, Y.N. Fang, J. Xing, T. Thu Ha Do, T.J. White, H.G. Li, W. Huang and Qihua Xiong*, “Manipulating efficient light emission in two-dimensional perovskite crystals by pressure-induced anisotropic deformation”, Science Advances 5, eaav9445 (2019) (Highlighted by Nature website and Nature Review Chemistry journal)
12. X.L. Wen, W.G. Xu, W.J. Zhao, J.B. Khurgin and Qihua Xiong*, “Plasmonic hot carriers controlled second harmonic generation in WSe2 bilayers”, Nano Lett. 18, 1686-1692 (2018)
13. C.Y. Jiang, W.G. Xu, A. Rasmita, Z.M. Huang, K. Li, Qihua Xiong* and W.B. Gao*, “Microsecond dark-exciton valley polarization memory in two-dimensional heterostructures”, Nature Communications 9, 753, Doi:10.1038/s41467-018-03174-3 (2018) (Editors’ Highlights)
14. G.K. Long, C.Y. Jiang, R. Sabatini, Z.Y. Yang, M.Y. Wei, L.N. Quan, Q.M. Liang, A. Rasmita, M. Askerka, G. Walters, X.W. Gong, J. Xing, X.L. Wen, R. Quintero-Bermudez, H.F. Yuan, G.C. Xing, X.R. Wang, D.T. Song, O. Voznyy, M.T. Zhang, S. Hoogland, W.B. Gao*, Qihua Xiong* and E.H. Sargent*, “Spin control in reduced-dimensional chiral perovskites”, Nature Photonics 12, 528-533 (2018)
15. T. Thu Ha Do, A. Granados del Aguila, C. Cui, J. Xing, Z.J. Ning* and Qihua Xiong*, “Optical study on intrinsic exciton states in a high-quality CH3NH3PbBr3 single crystal”, Phys. Rev. B 96, 075308 (2017)
二维半导体异质结超快电荷及能量传递效应:
1. Z.H. Hu*, T. Krisnanda, A. Fieramosca, J.X. Zhao, Q.L. Sun, Y.Z. Chen, H.Y. Liu, Y. Luo, R. Su, J.Y. Wang, K. Watanabe, T. Taniguchi, G. Eda, X.R. Wang, S. Ghosh, K. Dini*, D. Sanvitto, T.C.H. Liew, and Qihua Xiong*, “Energy transfer driven brightening of MoS2 by ultrafast polariton relaxation in microcavity MoS2/hBN/WS2 heterostructures”, Nature Communications 15, 1747 (2024)
2. Q. Lv#, J.Y. Tan#, Z.J. Wang#, P. Gu#, H.Y. Liu, L.X. Yu, Y.P. Wei, L. Gan, B.L. Liu*, J. Li*, F.Y. Kang, H.-M. Cheng, Qihua Xiong*, and R.T. Lv*, “Ultrafast charge transfer in mixed-dimensional WO3-x nanowire/WSe2 heterostructures for attomolar-level molecular sensing”, Nature Communications 14, 2717. DOI: 10.1038/s41467-023-38198-x (2023)
3. Y.F. Zhang#, Q. Lv#, H.D. Wang*, S.Y. Zhao, Qihua Xiong, R.T. Lv*, and X. Zhang*, “Simultaneous electrical and thermal rectification in a monolayer lateral heterojunction”, Science 378, 169-175 (2022)
4. H. Li, H.L. Li, X.Z. Wang, Y.F. Nie, C. Liu, Y. Dai, J.Y. Ling, M.N. Ding, X. Ling, D.Q. Xie, N. Lu, C.J. Wan, Qihua Xiong*, and W.G. Xu*, “Spontaneous Polarity Flipping in a 2D Heterobilayer Induced by Fluctuating Interfacial Carrier Flows”, Nano Lett. 21, 6773–6780 (2021)
5. Z.H. Hu, P.L. Hernández-Martínez, X. Liu, M.-R. Amara, W.J. Zhao, K. Watanabe, T. Taniguchi, H.V. Demir and Qihua Xiong*, “Trion-mediated Förster resonance energy transfer and optical gating effect in WS2/hBN/MoSe2 heterojunction”, ACS Nano 14, 13470–13477, DOI: 10.1021/acsnano.0c05447 (2020)
6. X. Liu, J.J. Pei, Z.H. Hu, W.J. Zhao, S. Liu, M.-R. Amara, K. Watanabe, T. Taniguchi, H. Zhang, and Qihua Xiong*, “Manipulating charge and energy transfer between 2D atomic layers via heterostructure engineering”, Nano Lett. 20, 5359–5366 (2020)
7. W. Du, J.X. Zhao, W.J. Zhao, S.P. Zhang, H.X. Xu and Qihua Xiong*, “Ultrafast modulation of exciton–plasmon coupling in a monolayer WS2–Ag nanodisk hybrid system”, ACS Photonics 6, 2832-2840 (2019)
8. C.Y. Jiang, A. Rasmita, W.G. Xu, A. Imamoglu, Qihua Xiong* and G.B. Gao*, “Optical spin pumping induced pseudomagnetic field in two-dimensional heterostructures”, Phys. Rev. B 98, 241410 (2018) (Rapid Communications)
9. W.J. Zhao and Qihua Xiong*, “Nanoscale interfaces made easily”, Nature 553, 32-34 (2018) (News and Views)
10. C.Y. Jiang, A. Rasmita, W.G. Xu, A. Imamoglu, Qihua Xiong* and G.B. Gao*, “Optical spin pumping induced pseudomagnetic field in two-dimensional heterostructures”, Phys. Rev. B 98, 241410 (2018) (Rapid Communications)
11. W.G. Xu, W.W. Liu, J. F. Schmidt, W.J. Zhao, X. Lu, T. Raab, C. Diederichs, W.B. Gao, D. V. Seletskiy, and Qihua Xiong*, “Correlated fluorescence blinking in two-dimensional semiconductor heterostructures”, Nature 541, 62-67 (2017)
12. H.K. Yu, D. Talukdar, W.G. Xu, J.B. Khurgin* and Qihua Xiong*, "Charge-Induced Second-Harmonic Generation in Bilayer WSe2", Nano Lett. 15, 5653-5657 (2015)
半导体光增益、光子学及光电子学器件:
1. Y. Chen#, J.G. Feng#,*, Y.Q. Huang#, W.J. Chen, R. Su, S. Ghosh, Y. Hou, Qihua Xiong*, and C.-W. Qiu*, “Compact spin-valley-locked perovskite emission”, Nature Materials, DOI:10.1038/s41563-023-01531-2 (2023)
2. L. Ferrier*, P. Bouteyre*, A. Pick, S. Cueff, N. H. M Dang, C. Diederichs, A. Belarouci, T. Benyattou, J. X. Zhao, R. Su, J. Xing, Qihua Xiong, and H. S. Nguyen*, “Unveiling the enhancement of spontaneous emission at exceptional points”, Phys. Rev. Let. 129, 083602, DOI: 10.1103/PhysRevLett.129.083602 (2022)
3. C.Y. Jiang, A. Rasmita, H. Ma, Q.H. Tan, Z.W. Zhang, Z.M. Huang, S. Lai, N.Z. Wang, S. Liu, X. Liu, T. Yu, Qihua Xiong*, and W.-B. Gao*, “A room-temperature gate-tunable bipolar valley Hall effect in molybdenum disulfide/tungsten diselenide heterostructures”, Nature Electron. 5, 23–27 (2022)
4. Y. Chen, W. Du, Q. Zhang, O. Ávalos-Ovando, J. Wu, Q.-H. Xu, N. Liu, H. Okamoto, A.O. Govorov, Qihua Xiong*, and Cheng-Wei Qiu*, “Multidimensional nanoscopic chiroptics”, Nature Review Physics, DOI: 10.1038/s42254-021-00391-6 (2021) (Perspectives)
5. Q. Zhang*, Q.Y. Shang, R. Su, T. Thu Ha Do, and Qihua Xiong*, “Halide perovskite semiconductor lasers: materials, cavity design, and low threshold”, Nano Lett. 21 DOI: 10.1021/acs.nanolett.0c03593 (2021)
6. K.B. Lin, J. Xing, L.N. Quan, F. Pelayo García de Arquer, X.W. Gong, J.X. Lu, L.Q. Xie, W.J. Zhao, D. Zhang, C.Z. Yan, W.Q. Li, X.Y. Liu, Y. Lu, J. Kirman, E.H. Sargent*, Qihua Xiong*, and Z.H. Wei*, “Perovskite light-emitting diodes with external quantum efficiency exceeding 20 per cent”, Nature 562, 245-248 (2018)
7. J. Xing, Y.B. Zhao, M. Askerka, L.N. Quan, X.W. Gong, W.J. Zhao, J.X. Zhao, H.R. Tan, G.K. Long, L. Gao, Z.Y. Yang, O. Voznyy, J. Tang, Z.H. Lu*, Qihua Xiong* and E.H. Sargent*, “Color-stable highly luminescent sky-blue perovskite light-emitting diodes” Nature Communications, DOI: 10.1038/s41467-018-05909-8 (2018)
8. F. Yan, J. Xing, G.C. Xing, L. Quan, S.T. Tan, J.X. Zhao, R. Su, L.L. Zhang, S. Chen, Y.W. Zhao, A. Huan, E.H. Sargent*, Qihua Xiong* and H.V. Demir*, “Highly efficient visible colloidal lead-halide perovskite nanocrystal light-emitting diodes”, Nano Lett. 18, 3157-3164 (2018)
9. Q. Zhang, R. Su, X.F. Liu, T.Z. Sum* and Qihua Xiong*, “High quality whispering-gallery-mode lasing from cesium lead halide perovskite nanoplatelets”, Adv. Funct. Mater. 26, 6238-6245 (2016)
10. J. Xing, F. Yan, Y.W. Zhao, S. Chen, H.K. Yu, Q. Zhang, R.G. Zeng, H.V. Demir, X.W. Sun, A. Huan and Qihua Xiong*, “High-efficiency light-emitting diodes of organometal halide perovskite amorphous nanoparticles”, ACS Nano 10, 6623-6630 (2016)
11. J. Xing, F. Yan, Y.W. Zhao, S. Chen, H.K. Yu, Q. Zhang, R.G. Zeng, H.V. Demir, X.W. Sun, A. Huan and Qihua Xiong*, “High-efficiency light-emitting diodes of organometal halide perovskite amorphous nanoparticles”, ACS Nano 10, 6623-6630 (2016)
12. J. Xing, X.F. Liu, Q. Zhang, S.T. Ha, Y.W. Yuan, C. Shen, T.C. Sum and Qihua Xiong*, "Vapor phase synthesis of organometal halide perovskite nanowires for tunable room-temperature nanolasers", Nano Lett. 15, 4571 - 4577 (2015)
13. Q. Zhang, S.T. Ha, X.F. Liu, T.C. Sum* and Qihua Xiong*, “Room-temperature near-infrared high-Q perovskite whispering-gallery planar nanolasers”, Nano Lett. 14, 5995-6001 (2014)
14. S.T. Ha, X.F. Liu, Q. Zhang, D. Giovanni, T.C. Sum and Qihua Xiong*, “Synthesis of organic-inorganic lead halide perovskite nanoplatelets: Towards high performance perovskite solar cells and opto-electronic devices”, Adv. Opt. Mater. 2, 838-844 (2014) (highlighted as Best of Advanced Optical Materials – 2014 edition)
15. Q. Zhang, G.Y. Li, X.F. Liu, F. Qian, Y. Li, T.C. Sum, C.M. Lieber* and Qihua Xiong*, “A room temperature low-threshold ultraviolet plasmonic nanolaser”, Nature Communications 5, 4953. DOI: 10.1038/ncomms5953 (2014)
拉曼光谱学、半导体光制冷及光学声子可分辨边带拉曼制冷效应:
1. J. Zhang*, Q. Zhang, X.Z. Wang, K. L. Kwek and Qihua Xiong*, “Resolved sideband Raman cooling of an optical phonon in semiconductor materials”, Nature Photonics 10, 600-605 (2016)
2. S.T. Ha, C. Shen, J. Zhang and Qihua Xiong*, “Laser cooling of organic-inorganic lead halide perovskites”, Nature Photonics 10, 115-121 (2016)
3. Q. Zhang, X.F. Liu, M.I.B. Utama, G.C. Xing, T.C. Sum* and Qihua Xiong*, “Phonon-assisted anti-Stokes lasing in ZnTe nanoribbons”, Adv. Mater. 28, 276-283 (2016)
4. X. Luo, X. Lu, G.K. Wai Koon, A.H.C. Neto, B. Özyilmaz*, Qihua Xiong*, and S.Y. Quek*, "Large frequency change with thickness in interlayer breathing mode — significant interlayer interactions in few layer black phosphorus", Nano Lett. 15, 3931-3938 (2015)
5. D.H. Li, J. Zhang, X.J. Wang, B.L. Huang and Qihua Xiong*, “Solid-state semiconductor optical cryocooler based on CdS nanobelts”, Nano Lett. 14, 4724–4728 (2014)
6. J. Zhang, D.H. Li, R.J. Chen, and Qihua Xiong*, “Laser cooling of a semiconductor by 40 Kelvin”, Nature 493, 504-508 (2013) (Nature Cover Highlight, highlighted by Nature Photonics in its April and May issues, news coverage by German Public Radio, German Science News, Physics world by IoP, Txchnologist, Arstechnia, The Statesman-The Oldest English Newspaper of India, Wiley Materials Views China, Phys Org, Channel Asia, The Strait Times, and so forth)
7. Y.Y. Zhao, X. Luo, H. Li, J. Zhang, P.T. Araujo, C.K. Gan, J. Wu, H. Zhang*, S.Y. Quek*, M.S. Dresselhaus, and Qihua Xiong*, “Interlayer breathing and shear modes in few-trilayer MoS2 and WSe2”, Nano Lett. 13, 1007-1015 (2013)
8. Q. Zhang, X.F. Liu, M.I.B. Utama, J. Zhang, M. de la Mata, J. Arbiol, Y.H. Lu, T.C. Sum, and Qihua Xiong*, “Highly enhanced exciton recombination rate by strong electron-phonon coupling in single ZnTe nanobelt”, Nano Lett. 12, 6420-6427 (2012)
9. Q. Zhang, J. Zhang, M.I.B. Utama, B. Peng, M. de la Mata, J. Arbiol, and Qihua Xiong*, “Exciton-phonon coupling in individual ZnTe nanorods studied by resonant Raman spectroscopy”, Phys. Rev. B 85, 085418 (2012)
10. J. Zhang, Z.P. Peng, A. Soni, Y.Y. Zhao, Y. Xiong, B. Peng, J.B. Wang, M.S. Dresselhaus, and Qihua Xiong*, “Raman spectroscopy of few-quintuple layer topological insulator Bi2Se3 nanoplatelets”, Nano Lett. 11, 2407-2414 (2011)
部分专利及授权:
1. Qihua Xiong, Bo Peng, “Monolayer of Nanorods on A Substrate and Method of Forming The Same”. US Patent Application No: 14/773, filing date: September 4th 2015. US Patent granted on August 7th, 2018 (Patent No. US 10,041,886 B2, pending); China Patent Application Number: 201480017158.8, patent granted on October 13th, 2017 (Patent No.: ZL 2014 8 0017158.8, pending).
2. Qihua Xiong, S.T. Ha, C. Shen and J. Zhang, “Laser Cooling of Organic-Inorganic Lead Halide Perovskites” US Provisional Patent (Application Number is TD/165/14), June 24th, 2014; granted on December 24th, 2019 (Patent No.: US 10,514,188 B2, pending).
3. Qihua Xiong, C. Cao and J. Zhang, “Alphabetical Metamaterial Gate/Sensor Device and Its Use to Measure Mercury”, US Provisional Patent (Application Number is 61/833,130), 10th June 2013; granted on November 5th, 2019 (Patent No.: US 10,466,180 B2, pending)
4. Qihua Xiong, C. Cao and J. Zhang, “Metamaterial Device and Uses Thereof”, Chinese patent Application Number: 201480033310.1, granted on August 7th, 2018. (Patent No.: ZL201480033310.1, pending)
5. Qihua Xiong and B. Peng, “Vertical-Aligned Monolayer of Au Nanorods On Arbitrary Substrates: Femtomolar Detection Of Phthalate Plasticizers”, PAT/046/13/13/US PRV, 5 April, 2013 (Application number 61/773,617).
6. Qihua Xiong, J. Zhang and D.H. Li, “Laser Cooling Of Solids Using II-VI Semiconductors”, Technology disclosure filed at Nanyang Technological University (Application number: 61/656,185) on 6 June 2012; US Patent Application No: 13/911,825, Filing Date: 06 June 2013; US patent granted on June 13th, 2017 (Patent No.: US 9,680,278 B2, pending).
7. Qihua Xiong, X.L. Xu and J. Zhang, “Flexible Vis-IR Metamaterials and Their Applications in Highly Sensitive Chemical and Biological Sensing”, Technology disclosure filed at Nanyang Technological University (Application number: 61/494,099), International filing date 6 June 2012; United States of America Application No.: 14/124,496, Filing Date: 6 December 2013. PAT/069/11/13/PCT-SG, pending. Chinese Patent granted on March 22nd, 2017 (Patent No.: ZL 2012 8 0028198.3). US Patent granted on June 20th 2017 (Patent No.: US 9,683, 991 B2, pending).
8. C.M. Lieber, Qihua Xiong, P. Xie and Y. Fang, “High-Resolution Molecular Sensor,” US Serial Number 12/677,573, granted on 15 April 2014 (Patent Number: US 8,698,481 B2) and European application Number 08830263.3 (Pending), licensed to Oxford Nanopore Technology, UK.
9. Chinese Patent: "A Piece of Equipment for DNA Chip Detecting", Chinese Patent Office, Qihua Xiong, Minqian Li, Bin Li, ZL 99 2 40088.0, application date: 10/29/99, issue date: 03/29/01.