姓名： 钟晓岚

职称：教授

办公电话：13811181528

Email：zhongxl@buaa.edu.cn

办公地点：C座620

研究方向：微纳光子学

个人简介：

钟晓岚，教授，博士生导师。2014年毕业于中国科学院物理研究所获得光学博士学位。2013年4月-2017年5月先后在新加坡国立大学和法国斯特拉斯堡大学超分子科学与工程研究所做博士后研究。2017年6月，经北京航空航天大学“卓越百人”计划加入北航物理学院。从2008年起从事微纳光子学研究，特别是在光与物质强耦合相互作用、微纳功能性薄膜材料、表面等离子体光学等方面，具有丰富的研究经验。创新性地建立并发展了多套基于表面等离子体光学的光与物质相互作用的全解析理论，并将理论与实验相结合，发现了基于光与物质强耦合相互作用下的非辐射能量转移，转移效率高达100%。在此研究基础上，实现了国际首例非局域相干纠缠态下的超距非辐射能量转移，突破了传统能量转移极限两个量级以上，同时发展了腔量子电动力学强耦合理论，提出“自下而上”的强耦合能级设计。在微纳功能性薄膜材料方面，深入解析多场调控电子-离子双注入模型获得离子存储器件性能提升的关键技术，开发了具有宽温区自适应性的自充电储能一体化智能器件。

发表SCI文章70余篇，包括Nature Nanotechnology,Angewandte Chemie International Edition,ACS Nano,Nano Energy,Journal of Materials Chemistry A,Physical Review系列等，总引用3000余次，H因子29，单篇最高引用超过450次。主持/参与科研项目10余项，其中包括国家自然科学基金、北京市自然科学基金、北航卓越百人支持计划，北航青年拔尖人才支持计划等。获中国感光学会科学技术二等奖（排名：3/6，2021年）；参与撰写中文著作《纳米光子学研究前沿》；本领域国际会议做邀请报告、口头报告和海报20余次，并应多所著名大学及科研院所邀请做学术报告。研究成果得到了相关领域国际学术界的广泛关注。

教育背景：

2011.9-2014.1

中国科学院物理研究所 光学 博士

从事纳米光子学，表面等离子体光学的实验及理论研究

2013.4-2013.10

新加坡国立大学访问学者

2008.9-2011.7

首都师范大学 光学 硕士

2004.9-2008.7

首都师范大学物理学 本科

工作经历：

2017.6-至今

北京航空航天大学 物理学院 教授 博士生导师

研究兴趣集中在微纳光子学、表面等离子体光学、光与物质强耦合相互作用、功能性薄膜材料等

2014.1-2017.5

法国斯特拉斯堡大学University of Strasbourg 博士后

光与物质强耦合相互作用

课题组主页（或个人主页）：

http://shi.buaa.edu.cn/zhongxiaolan/zh_CN/index.htm

代表性学术成果:

Leading author works

1.Solar Energy Materials and Solar Cells(2023)–Tian, M.^†; Liu, X.^†; Diao, X.;Zhong, X.^*High Performance PANI/MnO₂Coral-like Nanocomposite Anode for Flexible and Robust Electrochromic Energy Storage Device.,253, 112239. [IF:7.305 Q1]

2.Chemical Engineering Journal(2023)–Su, Y.; Wang, Y.; Lu, Z.; Tian, M.; Wang, F.; Wang, M.; Diao, X.;Zhong, X.^*A Dual-Function Device with High Coloring Efficiency Based on a Highly Stable Electrochromic Nanocomposite Material.,456, 141075. [IF:16.744 Q1]

3.Front. Phys.(2023)–Li, Z.; Li, X.; Zhang, G.Zhong, X.^*Realizing Strong Photon blockade at Exceptional points in 1 weak coupling regime.11, 1168372. [IF:3.9 Q2]

4.Opt. Express(2023)–Song, J.; Liu, B.; Shan,X.^*; Wang, F.;Zhong, X.^*Multi-functional dual-path self-aligned polarization interference lithography. 31(11) 17629-17644. [IF:3.833 Q2]

5.Opt. Express(2023)–Li, Z.; Li, X.;Zhong, X.^*Optomechanical entanglement affected by exceptional point in a WGM resonator system.Opt. Express20230631, 19382. [IF:3.833 Q2]

6.Opt. Express(2023)–Zhu, H.;Li, X.; Li, Z.; Wang, F.;Zhong, X.^*Strong antibunching effect under the combination of conventional and unconventional photon blockade. 31, 22030. [IF:3.833 Q2]

7.Chinese Phys. B(2023)–Li, X; Liu F.; Li, Z.; Zhu, H.; Wang F.;Zhong, X.^*https://doi.org/10.1088/1674-1056/acd7d2

8.J. Mater. Chem. A(2022)–Wang, Y.;Zhong, X.^*; Liu, X.; Lu, Z.; Su, Y.; Wang, M.; Diao, X. A Fast Self-Charging and Temperature Adaptive Electrochromic Energy Storage Device. 10 (8), 3944–3952.. [IF:14.511 Q1published as a cover paper]

9.J. Phys. Chem. Lett.(2021)–Tian, M.; Li, X.; Li, Z.;Zhong, X.^*Analysis of the Forward and Reverse Strongly Coupled States on the Nonradiative Energy Transfer Effect. 12 (20), 4944–4950.. [IF:6.888 Q1]

10.Phys. Rev. A(2021)–Li, Z.; Li, X.;Zhong, X.^*Strong Photon Blockade in an All-Fiber Emitter-Cavity Quantum Electrodynamics System. 103 (4), 043724. [IF:2.971 Q2]

11.Journal of Inorganic Materials(2021)–Zhong, X.; Liu, X.; Diao, X.^*Electrochromic Devices Based on Tungsten Oxide and Nickel Oxide: a Review. 36 (2), 128. [IF:1.292 Q3published as a invited cover paper]

12.Phys. Chem. Chem. Phys.(2021)–Lu, Z.;Zhong, X.^*; Liu, X.; Wang, J.; Diao, X.^*Energy Storage Electrochromic Devices in the Era of Intelligent Automation.23(26), 14126–14145. [IF:3.945 Q1]

13.Eur. Phys. J. Spec. Top.(2021)–Zhu, H.; Li, X.; Li, Z.;Zhong, X.^*A Robust and Flexible High-Order Photon Blocking Effect Based on Drive Ratio Analysis.231,735-742.[IF:2.891 Q2]

14.Solar Energy Materials and Solar Cells(2020)–He, Y.; Jones, T. W.; Anderson, K. F.; Duffy, N. W.; Wang, M.; Dong, G.;Zhong, X.^*; Wilson, G. J.^*; Diao, X.^*An Extensible and Tunable Full-Opaque Cascade Smart Electrochromic Device. 218, 110740. [IF:7.305 Q1]

15.J. Phys. Chem. C(2020)–Li, X.; Liu, F.; Tian, M.;Zhong, X.^*Tunable Multimode Plasmon–Exciton Coupling for Absorption-Induced Transparency and Strong Coupling. 124 (43), 23888–23894. [IF:4.177 Q2]

16.Electrochimica Acta(2020)–Yu, H.; Guo, J.; Wang, C.; Zhang, J.; Liu, J.; Dong, G.;Zhong, X.^*; Diao, X.^*Essential Role of Oxygen Vacancy in Electrochromic Performance and Stability for WO3-y Films Induced by Atmosphere Annealing. 332, 135504. [IF:7.336 Q1]

17.Electrochimica Acta(2019)–Yu, H.; Guo, J.; Wang, C.; Zhang, J.; Liu, J.;Zhong, X.^*; Dong, G.; Diao, X.^*High Performance in Electrochromic Amorphous WO_xFilm with Long-Term Stability and Tunable Switching Times via Al/Li-Ions Intercalation/Deintercalation. 318, 644–650. [IF:7.336 Q1]

18.Electrochimica Acta(2019)–He, Y.; Li, T.;Zhong, X.^*; Zhou, M.^*; Dong, G.; Diao, X.^*Lattice and Electronic Structure Variations in Critical Lithium Doped Nickel Oxide Thin Film for Superior Anode Electrochromism. 316, 143–151. [IF:7.336 Q1]

19.Nano Energy(2019)–Liu, L.; Du, K.; He, Z.; Wang, T.;Zhong, X.^*; Ma, T.; Yang, J.; He, Y.; Dong, G.; Wang, S.; Diao, X.^*High-Temperature Adaptive and Robust Ultra-Thin Inorganic All-Solid-State Smart Electrochromic Energy Storage Devices. 62, 46–54. [IF:19.069 Q1]

20.J. Mater. Chem. A(2019)–Li, Y.^†*;Zhong, X.^†; Luo, K.; Shao, Z.^*A Hydrophobic Polymer Stabilized P-Cu₂O Nanocrystal Photocathode for Highly Efficient Solar Water Splitting. 7 (26), 15593–15598. [IF:14.511 Q1]

21.Electrochimica Acta(2018)–He, Y.; Zhang, F.; Zhang, Q.; Dong, G.;Zhong, X.^*; Diao, X.^*High Capacity and Performance Lithium Based Electrochromic Device via Amorphous Tantalum Oxide Protective Layer. 280, 163–170. [IF:7.336 Q1]

22.Angew. Chem. Int. Ed.(2017)–Zhong, X.; Chervy, T.; Zhang, L.; Thomas, A.; George, J.; Genet, C.; Hutchison, J. A.; Ebbesen, T. W.^*Energy Transfer between Spatially Separated Entangled Molecules. 56 (31), 9034–9038. [IF:16.823 Q1ESIhigh citation paper]

23.Angew. Chem. Int. Ed.(2016)–Zhong, X.; Chervy, T.; Wang, S.; George, J.; Thomas, A.; Hutchison, J. A.; Devaux, E.; Genet, C.; Ebbesen, T. W.^*Non-Radiative Energy Transfer Mediated by Hybrid Light-Matter States. 55 (21), 6202–6206. [IF:16.823 Q1published as ahotpaper]

24.ACS Nano(2016)–Zhong, X.; Rodrigo, S. G.; Zhang, L.; Samorì, P.; Genet, C.; Martín-Moreno, L.; Hutchison, J. A.^*; Ebbesen, T. W. Waveguide and Plasmonic Absorption-Induced Transparency. 10 (4), 4570–4578.

25.Chin. Opt. Lett.(2014)–Zhong, X.; Liu, J.; Li, Z.^*Highly Enhanced Broadband Infrared Absorption of Germanium by Multi-Layer Plasmonic Nano-Antenna. 12 (9), 092401–092404.

26.Appl. Phys. A(2014)–Zhong, X.; Hong, M.; Li, Z.^*Spaser in Plasmonic Nano-Antenna Evaluated by an Analytical Theory. 115 (1), 5–11.

27.Phys. Rev. B(2013)–Zhong, X.; Li, Z.^*All-Analytical Semiclassical Theory of Spaser Performance in a Plasmonic Nanocavity. 88 (8), 085101.

28.J. Opt.(2012)–Zhong, X..; Li, Z.^*Plasmon Enhanced Light Amplification in Metal–Insulator–Metal Waveguides with Gain. 14 (5), 055002.

29.Journal of Modern Optics(2012)–Zhong, X.; Li, Z.^*; Meng, Z.; Zhou, Y. Mode Analysis for Periodically Modulated Metal Slits. 59 (9), 830–838.

30.J. Phys. Chem. C(2012)–Zhong, X.; Li, Z.^*Giant Enhancement of Near-Ultraviolet Light Absorption by TiO 2 via a Three-Dimensional Aluminum Plasmonic Nano Funnel-Antenna. 116 (40), 21547–21555.

31.Journal of Applied Physics(2011)–Zhong, X.; Li, Z.^*; Wang, C.; Zhou, Y. Analytical Single-Mode Model for Subwavelength Metallic Bragg Waveguides. 109 (9), 093115.

Collaborative works

32.Opt. Express(2023)–Wang, D.; Liu, B.; Song, J.; Wang, Y.; Shan, X.;Zhong, X.; Wang, F. Dual-Mode Adaptive-SVD Ghost Imaging. 31 (9), 14225.

33.Adv Materials Inter(2022)–Ding, Y.; Wang, M.; Mei, Z.; Liu, L.; Yang, J.;Zhong, X.; Wang, M.; Diao, X. Electrochromic Adaptability of NiO_xFilms Modified by Substrate Temperature in Aqueous and Non‐Aqueous Electrolytes.9(17), 2102223.

34.Vacuum(2022)–Ding, Y.; Wang, M.; Mei, Z.; Liu, L.;Zhong, X.; Wang, M.; Diao, X. Enhanced Electrochromic Performance on Novel W@NiO Doped Composite Electrode via Pre-Annealing. 201, 111070.

35.Nano Lett. (2022)–Chen, C.; Ding, L.; Liu, B.; Du, Z.; Liu, Y.; Di, X.; Shan, X.; Lin, C.; Zhang, M.; Xu, X.;Zhong, X.; Wang, J.; Chang, L.; Halkon, B.; Chen, X.; Cheng, F.; Wang, F. Exploiting Dynamic Nonlinearity in Upconversion Nanoparticles for Super-Resolution Imaging. 22 (17), 7136–7143.

36.Chemical Engineering Journal(2021)–Liu, L.; Wang, T.; He, Z.; Yi, Y.; Wang, M.; Luo, Z.; Liu, Q.; Huang, J.;Zhong, X.; Du, K.; Diao, X. All-Solid-State Electrochromic Li-Ion Hybrid Supercapacitors for Intelligent and Wide-Temperature Energy Storage. 414, 128892.

37.Energy Technol.(2021)–Che, X.; Guo, J.; Wang, M.; Wang, M.;Zhong, X.; Liu, Q.; Dong, G.; Wang, X.; Yang, J.; Diao, X. Thickness Dependence of WO₃and NiO_xThin Films in All‐Solid‐State Complementary Electrochromic Devices. 9 (12), 2100656.

38.Journal of Alloys and Compounds(2020)–Wang, C.; Dong, G.; Zhao, Y.; He, Y.; Ding, Y.; Du, X.;Zhong, X.; Wang, M.; Diao, X. Enhanced Electrochromic Performance on Anodic Nickel Oxide Inorganic Device via Lithium and Aluminum Co-Doping. 821, 153365.

39.ACS Appl. Mater. Interfaces(2020)–Du, L.; Sun, N.; Chen, Z.; Li, Y.; Liu, X.;Zhong, X.; Wu, X.; Xie, Y.; Liu, Q. Depletion-Mediated Uniform Deposition of Nanorods with Patterned, Multiplexed Assembly. 12 (43), 49200–49209.

40.Energy Storage Materials(2020)–Liu, L.; Diao, X.; He, Z.; Yi, Y.; Wang, T.; Wang, M.; Huang, J.; He, X.;Zhong, X.; Du, K. High-Performance All-Inorganic Portable Electrochromic Li-Ion Hybrid Supercapacitors toward Safe and Smart Energy Storage. 33, 258–267.

41.ACS Nano(2019)–Li, S.-L.; Zhang, L.;Zhong, X.; Gobbi, M.; Bertolazzi, S.; Guo, W.; Wu, B.; Liu, Y.; Xu, N.; Niu, W.; Hao, Y.; Orgiu, E.; Samorì, P. Nano-Subsidence-Assisted Precise Integration of Patterned Two-Dimensional Materials for High-Performance Photodetector Arrays. 13 (2) 2654-2662.

42.Electrochimica Acta(2019)–Wang, M.; Barnabé, A.; Thimont, Y.; Wang, J.; He, Y.; Liu, Q.;Zhong, X.; Dong, G.; Yang, J.; Diao, X. Optimized Properties of Innovative ElectroChromic Device Using ITO / Ag / ITO Electrodes. 301, 200–208.

43.J. Mater. Chem. A(2019)–Liu, L.; Zhang, Q.; Du, K.; He, Z.; Wang, T.; Yi, Y.; Wang, M.;Zhong, X.; Dong, G.; Diao, X. An Intelligent and Portable Power Storage Device Able to Visualize the Energy Status. 7 (40), 23028–23037.

44.Nanoscale(2019)–Squillaci, M. A.;Zhong, X.; Peyruchat, L.; Genet, C.; Ebbesen, T. W.; Samorì, P. 2D Hybrid Networks of Gold Nanoparticles: Mechanoresponsive Optical Humidity Sensors. 11 (41), 19315–19318.

45.Electrochimica Acta(2018)–Xiao, Y.;Zhong, X.; Guo, J.; Zhou, C.; Zuo, H.; Liu, Q.; Huang, Q.; Zhang, Q.; Diao, X. The Role of Interface between LiPON Solid Electrolyte and Electrode in Inorganic Monolithic Electrochromic Devices. 260, 254–263.

46.J. Mater. Chem. C(2018)–Liu, Q.; Chen, Q.; Zhang, Q.; Xiao, Y.;Zhong, X.; Dong, G.; Delplancke-Ogletree, M.-P.; Terryn, H.; Baert, K.; Reniers, F.; Diao, X.In SituElectrochromic Efficiency of a Nickel Oxide Thin Film: Origin of Electrochemical Process and Electrochromic Degradation. 6 (3), 646–653.

47.Electrochimica Acta(2018)–Liu, Q.; Chen, Q.; Zhang, Q.; Dong, G.;Zhong, X.; Xiao, Y.; Delplancke-Ogletree, M.-P.; Reniers, F.; Diao, X. Dynamic Behaviors of Inorganic All-Solid-State Electrochromic Device: Role of Potential. 269, 617–623.

48.Solar Energy Materials and Solar Cells(2018)–Xiao, Y.; Dong, G.; Guo, J.; Liu, Q.; Huang, Q.; Zhang, Q.;Zhong, X.; Diao, X. Thickness Dependent Surface Roughness of Sputtered Li2.5TaOx Ion Conductor and Its Effect on Electro-Optical Performance of Inorganic Monolithic Electrochromic Device. 179, 319–327.

49.Adv. Mater.(2018)–Zhang, L.; Pasthukova, N.; Yao, Y.;Zhong, X.; Pavlica, E.; Bratina, G.; Orgiu, E.; Samorì, P. Self-Suspended Nanomesh Scaffold for Ultrafast Flexible Photodetectors Based on Organic Semiconducting Crystals. 30 (28), 1801181.

50.J. Am. Chem. Soc.(2017)–Zhang, L.; Li, S.; Squillaci, M. A.;Zhong, X.; Yao, Y.; Orgiu, E.; Samorì, P. Supramolecular Self-Assembly in a Sub-Micrometer Electrodic Cavity: Fabrication of Heat-Reversible π-Gel Memristor. 139 (41), 14406–14411.

51.Adv. Mater.(2017)–Zhang, L.; Pavlica, E.;Zhong, X.; Liscio, F.; Li, S.; Bratina, G.; Orgiu, E.; Samorì, P. Fast-Response Photonic Device Based on Organic-Crystal Heterojunctions Assembled into a Vertical-Yet-Open Asymmetric Architecture. 29 (11), 1605760.

52.Nature Nanotech.(2016)–Zhang, L.;Zhong, X.; Pavlica, E.; Li, S.; Klekachev, A.; Bratina, G.; Ebbesen, T. W.; Orgiu, E.; Samorì, P. A Nanomesh Scaffold for Supramolecular Nanowire Optoelectronic Devices. 11 (10), 900–906.

53.Angew. Chem. Int. Ed.(2016)–Thomas, A.; George, J.; Shalabney, A.; Dryzhakov, M.; Varma, S. J.; Moran, J.; Chervy, T.;Zhong, X.; Devaux, E.; Genet, C.; Hutchison, J. A.; Ebbesen, T. W. Ground-State Chemical Reactivity under Vibrational Coupling to the Vacuum Electromagnetic Field. 55 (38), 11462–11466.

54.J. Mater. Chem. C(2014)–Liao, Q.; Xu, Z.;Zhong, X.; Dang, W.; Shi, Q.; Zhang, C.; Weng, Y.; Li, Z.; Fu, H. An Organic Nanowire Waveguide Exciton–Polariton Sub-Microlaser and Its Photonic Application. 2 (15), 2773–2778.

55.Photonics and Nanostructures - Fundamentals and Applications(2014)–Meng, Z.-M.; Hu, Y.-H.; Wang, C.;Zhong, X.; Ding, W.; Li, Z.-Y. Design of High-Q Silicon-Polymer Hybrid Photonic Crystal Nanobeam Microcavities for Low-Power and Ultrafast All-Optical Switching. 12 (1), 83–92.

56.Chinese Phys. B(2014)–Liu, J.;Zhong, X.; Li, Z.-Y. Enhanced Light Absorption of Silicon in the Near-Infrared Band by Designed Gold Nanostructures. 23 (4), 047306.

57.Journal of Applied Physics(2014)–Meng, Z.-M.; Hu, Y.-H.; Ju, G.-F.;Zhong, X.; Ding, W.; Li, Z.-Y. Numerical Investigation of Optical Tamm States in Two-Dimensional Hybrid Plasmonic-Photonic Crystal Nanobeams. 116 (4), 043106.

58.Small(2014)–Yang, Y.;Zhong, X.; Zhang, Q.; Blackstad, L. G.; Fu, Z.-W.; Li, Z.-Y.; Qin, D. The Role of Etching in the Formation of Ag Nanoplates with Straight, Curved and Wavy Edges and Comparison of Their SERS Properties. 10 (7), 1430–1437.

59.Part. Part. Syst. Charact.(2013)–Zheng, Y.;Zhong, X.; Li, Z.; Xia, Y. Successive, Seed-Mediated Growth for the Synthesis of Single-Crystal Gold Nanospheres with Uniform Diameters Controlled in the Range of 5-150 nm. 31 (2), 266–273.

60.Chinese Phys. Lett.(2013)–Ren, M.-L.;Zhong, X.; Chen, B.-Q.; Li, Z.-Y. An All-Optical Diode Based on Plasmonic Attenuation and Nonlinear Frequency Conversion. 30 (9), 097301.

61.CrystEngComm(2013)–Kim, D. Y.; Choi, K. W.;Zhong, X.; Li, Z.-Y.; Im, S. H.; Park, O. O. Au@Pd Core–Shell Nanocubes with Finely-Controlled Sizes3. DOI: 10.1039/c3ce40175h.

62.Small(2013)–Li, Q.; Jiang, Y.; Han, R.;Zhong, X.; Liu, S.; Li, Z.-Y.; Sha, Y.; Xu, D. High Surface-Enhanced Raman Scattering Performance of Individual Gold Nanoflowers and Their Application in Live Cell Imaging. 9 (6), 927–932.

63.ChemSusChem(2013)–Laskar, M.;Zhong, X.; Li, Z.-Y.; Skrabalak, S. E. Manipulating the Kinetics of Seeded Growth for Edge-Selective Metal Deposition and the Formation of Concave Au Nanocrystals. 6 (10), 1959–1965.

64.CrystEngComm(2013)–Choi, K. W.; Kim, D. Y.;Zhong, X.; Li, Z.-Y.; Im, S. H.; Park, O. O. Robust Synthesis of Gold Rhombic Dodecahedra with Well-Controlled Sizes and Their Optical Properties. 15 (2), 252–258.

65.Chem. Asian J.(2013)–Zheng, Y.; Ma, Y.; Zeng, J.;Zhong, X.; Jin, M.; Li, Z.-Y.; Xia, Y. Seed-Mediated Synthesis of Single-Crystal Gold Nanospheres with Controlled Diameters in the Range 5-30 Nm and Their Self-Assembly upon Dilution. 8 (4), 792–799.

66.ACS Nano(2012)–Jin, M.; Zhang, H.; Wang, J.;Zhong, X.; Lu, N.; Li, Z.; Xie, Z.; Kim, M. J.; Xia, Y. Copper Can Still Be Epitaxially Deposited on Palladium Nanocrystals To Generate Core–Shell Nanocubes Despite Their Large Lattice Mismatch. 6 (3), 2566–2573.

67.Chin. Opt. Lett.(2012)–Ziming Meng, Z. M.;Zhong, X., X. Z.; Chen Wang, C. W.; Zhiyuan Li, Z. L. Fabrication of Air-Bridged Kerr Nonlinear Polymer Photonic Crystal Slab Structures in near-Infrared Region. 10 (11), 112202–112204.

68.Opt. Express(2012)–Qin, F.; Meng, Z.-M.;Zhong, X.; Liu, Y.; Li, Z.-Y. Fabrication of Semiconductor-Polymer Compound Nonlinear Photonic Crystal Slab with Highly Uniform Infiltration Based on Nano-Imprint Lithography Technique. 20 (12), 13091.

69.Small(2012)–Li, B.; Long, R.;Zhong, X.; Bai, Y.; Zhu, Z.; Zhang, X.; Zhi, M.; He, J.; Wang, C.; Li, Z.-Y.; Xiong, Y. Investigation of Size-Dependent Plasmonic and Catalytic Properties of Metallic Nanocrystals Enabled by Size Control with HCl Oxidative Etching. 8 (11), 1710–1716.

70.Sci Rep.(2012)–Wang, C.;Zhong, X.; Li, Z.-Y. Linear and Passive Silicon Optical Isolator. 2 (1), 674.

71.Nanotechnology(2012)–Ling, L.; Guo, H.-L.;Zhong, X.; Huang, L.; Li, J.-F.; Gan, L.; Li, Z.-Y. Manipulation of Gold Nanorods with Dual-Optical Tweezers for Surface Plasmon Resonance Control. 23 (21), 215302.

72.EPL(2012)–Meng, Z.-M.;Zhong, X.; Wang, C.; Li, Z.-Y. Numerical Investigation of High-Contrast Ultrafast All-Optical Switching in Low-Refractive-Index Polymeric Photonic Crystal Nanobeam Microcavities. 98 (5), 54002.

73.Advances in materials Research(2012)–Do Youb Kim; Kyeong Woo Choi; Sang Hyuk Im; O Ok Park;Zhong, X.; Zhi-Yuan Li. One-Pot Synthesis of Gold Trisoctahedra with High-Index Facets. 1 (1), 1–12.

74.Nanoscale(2012)–Xiong, Y.; Long, R.; Liu, D.;Zhong, X.; Wang, C.; Li, Z.-Y.; Xie, Y. Solar Energy Conversion with Tunable Plasmonic Nanostructures for Thermoelectric Devices. 4 (15), 4416.