孫磊，深圳大學(xué)長聘副教授，深圳市海外高層次人才，香港中文大學(xué)07級物理哲學(xué)博士，2012~2016年密蘇里科技大學(xué)訪問學(xué)者。2016年9月入職深圳大學(xué)。兼任美國物理學(xué)會（APS）審稿人，美國光學(xué)學(xué)會（OSA）審稿人。主要研究方向包括電磁波與功能性材料相互作用的理論計算和數(shù)值分析實驗，以及等效介質(zhì)理論的第一性原理的研究。

Dr. Lei Sun, Associate Professor , Oversea High-Caliber Personnel of Shenzhen, received the Ph.D. degree in Physics from the Chinese University of Hong Kong in 2011, worked as a visiting scholar at Missouri University of Science and Technology from 2012 to 2016, and joined Shenzhen University in 2016. Meanwhile, Dr. Sun holds a concurrent post as a reviewer for the American Physical Society (APS) and The Optical Society (OSA). Dr. Sun's primary research interest is the theory and simulation of material electromagnetic properties and the effective medium theory.

教育經(jīng)歷：

? 哲學(xué)博士，理論物理，香港中文大學(xué)物理系，2007/08–2011/12

? 理學(xué)碩士，凝聚態(tài)物理，南開大學(xué)物理科學(xué)學(xué)院，2003/09–2006/06

? 理學(xué)學(xué)士，物理學(xué)，南開大學(xué)物理科學(xué)學(xué)院，1999/09–2003/06

科研經(jīng)歷：

? 副教授，深圳大學(xué)，2023/07–至今

? 助理教授，深圳大學(xué)，2016/09–2023/06

? 訪問學(xué)者，美國密蘇里大學(xué)機(jī)械與航天工程系，2012/04–2016/06

? 初級研究助理，香港中文大學(xué)物理系，2010/12–2011/12

研究方向：

? 超材料，光子晶體，表面等離子體激元 (metamaterials, photonic crystals, surface plasmon polaritons)

? 米散射 (Mie scattering theory)

? 等效介質(zhì)理論 (effective medium theory)

研究成果：

[1] L. Sun and G. P. Wang, Broadband ENZ metamaterials and its application in optical field manipulation, Acta Photonica Sinica 51, 0151107 (2022). (特邀綜述)

[2] B. Hong, L. Sun, W. Wang, Y. Qiu, N. Feng, D. Su, N. Somjit, I. Robertson, and G. P. Wang, Five-channel frequency-division multiplexing using lowloss epsilon-near-zero metamaterial waveguide, Science China-Physics, Mechanics & Astronomy 65, 274211 (2022).

[3] D. Yang, F. Feng, L. Sun, N. Wang, and G. P. Wang, Realization of magneto-optical near-zero-index metamaterial by using an array of spinning cylinders, Physical Review A 105, 043517 (2022).

[4] Z. Liu, G. Wei, D. Zhang, W. Chen, L. Sun, J. Li, and J. J. Xiao, Strong frequency-dependent beam steering dynamics, Zitterbewegung effect, and Klein tunneling in a ternary plasmonic-dielectric superlattice, Physical Review B 103, 195415 (2021).

[5] H. Song, L. Sun, and G. P. Wang, Tunable perfect magnetic mirrors and retroreflectors in terahertz band, Optics Express 28, 753 (2020).

[6] H. Song, L. Sun, B. Hong, and G. P. Wang, Magnetic mirror by exciting magnetic quadrupole in dielectric metasurface, Journal of Optics 21, 125101 (2019).

[7] L. Sun, K. W. Yu, and G. P. Wang, Inverse design of broadband epsilon-near-zero metasurface with nanoscale airtube superlattice based on the Bergman-Milton spectral representation, Physical Review B 100, 125439 (2019).

[8] L. Sun, K. W. Yu, and G. P. Wang, Design anisotropic broadband epsilon-near-zero metamaterials: rigorous use of Bergman and Milton spectral representations, Physical Review Applied 9, 064020 (2018).

[9] L. Sun, J. Gao, and X. Yang, Klein tunneling near the Dirac points in metal-dielectric multilayer metamaterials, Scientific Reports 7, 9678 (2017).

[10] L. Sun, X. Yang, and J. Gao, Analysis of nonlocal effective permittivity and permeability in symmetric metal-dielectric multilayer metamaterials, Journal of Optics 18, 065101 (2016).

[11] L. Sun, J. Gao, and X. Yang, Optical nonlocality induced Zitterbewegung near the Dirac point in metal-dielectric multilayer metamaterials, Optics Express 24, 7055 (2016).

[12] L. Sun, Z. Li, T. S. Luk, X. Yang, and J. Gao, Nonlocal effective medium analysis in symmetric metal-dielectric multilayer metamaterials, Physical Review B 91, 195147 (2015).

[13] L. Sun, X. Yang, W. Wang, and J. Gao, Diffraction-free optical beam propagation with near-zero phase variation in extremely anisotropic metamaterials, Journal of Optics 17, 035101 (2015).

[14] L. Sun, F. Cheng, C. J. Mathai, S. Gangopadhyay, J. Gao, and X. Yang, Experimental characterization of optical nonlocality in metal-dielectric multilayer metamaterials, Optics Express 22, 22974 (2014).

[15] L. Sun, J. Gao, and X. Yang, Realizing broadband electromagnetic transparency with a graded-permittivity sphere, Journal of Optics. 16, 085101 (2014).

[16] L. Sun, X. Yang, and J. Gao, Loss-compensated broadband epsilon-near-zero metamaterials with gain media, Applied Physics Letters 103, 201109 (2013).

[17] L. Sun, J. Gao, and X. Yang, Giant optical nonlocality near the Dirac point in metal-dielectric multilayer metamaterials, Optics Express 21, 21542 (2013).

[18] L. Sun, J. Gao, and X. Yang, Broadband epsilon-near-zero metamaterials with steplike metal-dielectric multilayer structures, Physical Review B 87, 165134 (2013).

[19] L. Sun, S. Feng, and X. Yang, Loss enhanced transmission and collimation in anisotropic epsilon-near-zero metamaterials, Applied Physics Letters 101, 241101 (2012).

[20] L. Sun, K. W. Yu, and X. Yang, Integrated optical devices based on broadband epsilon-near-zero meta-atoms, Optics Letters 37, 3096 (2012).

[21] L. Sun and K. W. Yu, Strategy for designing broadband epsilon-near-zero metamaterial with loss compensation by gain media, Applied Physics Letters 100, 261903 (2012).

[22] L. Sun and K. W. Yu, Broadband transparency with a graded anisotropic metal-dielectric sphere, Journal of Optics 14, 055101 (2012).

[23] L. Sun and K. W. Yu, Strategy for designing broadband epsilon-near-zero metamaterials, Journal of the Optical Society of America B 29, 984 (2012).

[24] L. Sun and K. W. Yu, Broadband electromagnetic transparency by graded metamaterials: scattering cancellation scheme, Journal of the Optical Society of America B 28, 994 (2011).