团队队伍

汪能

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个人详情

汪能,副教授,深圳市海外高层次人才,复旦大学2010届物理学学士,2015届理论物理博士,2015~2019年香港科技大学物理系博士后。20193月加入永利集团。主要从事光学操控和人工微结构光子学等领域的研究。

教育经历:

l 博士,复旦大学,2010/092015/07

l 学士,复旦大学,2006/092010/07

科研经历:

l 副教授,永利集团,2023/07–至今

l 助理教授,永利集团,2019/032023/06

l 博士后,香港科技大学,2015/082019/02

研究方向:

l 光学操控 (optical manipulation)

l 人工微结构光子学 (artificial microstructure photonics)

l 时变超材料(time-varying metamaterials

主持项目:

l 国家自然科学基金委 面上项目, 2022-2025年, 53 万, 主持

l 国家自然科学基金委 青年项目, 2020-2022年, 25 万, 主持

l 广东省自然科学基金面上项目, 2019-2022年, 10万, 主持

l 深圳市高层次人才启动经费,2021-2023年, 270万, 主持

研究成果:

[1] N. Wang , R.-Y. Zhang, Q. Guo, S. Wang , G. P. Wang, and C. T. Chan, Optical pulling using topologically protected one way transport surface-arc waves, Physical Review B 105, 014104 (2022).

[2] L. Cui and N. Wang (通讯), Trapping and self-assembly of particles by photonic chiral surface waves, Physical Review A 105, 053512 (2022).

[3] D. Yang, F. Feng , L. Sun, N. Wang (共同通讯), 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).

[3] N. Wang, R.-Y. Zhang, and C. T. Chan, Optical forces on a cylinder induced by surface waves and the conservation of the canonical momentum of light, Optics Express 29, 20590 (2021).

[4] L. Cui, N. Wang (共同通讯), and J. Ng, Computation of internal optical forces using the Helmholtz tensor, Physical Review A 104, 013508 (2021).

[5] N. Wang and G. P. Wang, One-dimensional time-Floquet photonic crystal, New Journal of Physics 23, 103023 (2021).

[6] N. Wang, R.-Y. Zhang, and C. T. Chan, Robust acoustic pulling using chiral surface waves, Physical Review Applied 15, 024034 (2021).

[7] N. Wang, R.-Y. Zhang, C. T. Chan, and G. P. Wang, Effective medium theory for a photonic pseudospin-1/2 system, Physical Review B 102, 094312 (2020).

[8] H. Song , N. Wang (共同通讯), K. Yu, J. Pei, and G. P. Wang, Disorder-immune metasurfaces with constituents exhibiting the anapole mode, New Journal of Physics 22, 113011 (2020).

[9] N. Wang and G. P. Wang, Effective medium theory with closed-form expressions for bi-anisotropic optical metamaterials, Optics Express 27, 23739 (2019).

[10] N. Wang, S. Wang, Z.-Q. Zhang, C. T. Chan, Closed-form expressions for effective constitutive parameters: Electrostrictive and magnetostrictive tensors for bianisotropic metamaterials and their use in optical force density calculations, Physical Review B 98, 045426 (2018).

[11] N. Wang, Z.-Q. Zhang, and C. T. Chan, Photonic Floquet media with a complex time-periodic permittivity, Physical Review B 98, 085142 (2018).

[12] N. Wang, S. Wang, and J. Ng, Electromagnetic stress tensor for an amorphous metamaterial medium, Physical Review A 97, 033839 (2018).

[13] N. Wang, X. Li, J. Chen, Z. Lin, and J. Ng, Gradient and scattering forces of anti-reflection-coated spheres in an aplanatic beam, Scientific Reports 8, 1 (2018).

[14] N. Wang, W. Lu, J. Ng, and Z. Lin, Optimized optical "tractor beam" for core-shell nanoparticles, Optics Letters 39, 2399 (2014).

[15] N. Wang, Z. Lin, and J. Ng, Laser induced surface stress on water droplets, Optics Express 22, 23770 (2014).

[16] N. Wang, H. Chen, W. Lu, S. Liu, and Z. Lin, Giant omnidirectional radiation enhancement via radially anisotropic zero-index metamaterial, Optics Express 21, 23712 (2013).

[17] N. Wang, J. Chen, S. Liu, and Z. Lin, Dynamical and phase-diagram study on stable optical pulling force in Bessel beams, Physical Review A 87, 063812 (2013).

[18] N. Wang, S. Liu, and Z. Lin, Tailoring optical properties of surface charged dielectric nanoparticles based on an effective medium theory, Optics Express 21, 20387 (2013).