姓名:常凯楠
性别:男
职称:讲师
所在系所:物理系
所在梯队:理论物理梯队
办公地点:方兴大厦711
办公电话:无
电子邮件:knchang@ustb.edu.cn
本科生课程:无
研究生课程:无
研究领域:二维材料、拓扑材料、半金属、量子材料以及薄膜结构等体系中线性和非线性光学响应;载流子相干注入和相干控制;分子系统的动力学;异质结的能量转移;半导体光电器件的模拟仿真等。
二、教育经历
2009-2013,长春理工大学,理学院,学士
2013-2016,北京科技大学,数理学院,硕士
2016-2022,德国柏林洪堡大学,物理学院,博士
三、工作经历
2022-2025,中国科学院长春光学精密机械与物理研究所,特别研究助理/博士后
2025-2026,中国科学院长春光学精密机械与物理研究所,助理研究员
2026年至今,北京科技大学,数理学院,讲师
四、科研业绩
代表性论著
1. M. Zhou, H. Chen, K. Chang, D. Ding, L. Wang*. Time-reversal probe of spatially nonuniform information loss in open Rydberg atom arrays. Ann. Phys. (Under Review).
2. Z. Li#, K. Chang# (Co-first author), H. Li, Y. Gao, W. Xin, J. L. Cheng, H. Xu. Photocurrent effect in few layer graphene. Phys. Rev. B (Under Review).
3. H. Cui, H. Zhang, R. Yao, K. Chang, L. Wang*. Simulation of Exciton-Induced Transparency in Hybrid System of Chiral Metasurface and Molecular Layer. Chin. J. Phys. (2026) (Accepted).
4. P. Zhang, K. Chang*, L. Wang*. Dependence of electromagnetically induced transparency in molecular aggregates on structural configuration and applied field. Phys. Scr. (2026) (Accepted).
5. H. Li, K. Chang*, W-K Tse*, J. L. Cheng*. Photogalvanic effects in surface states of topological insulators under perpendicular magnetic fields. Chin. Phys. B 35, 054203 (2026).
6. K. Chang*, Y. Meng, Y. Qian, L. Wang*, J. L. Cheng*. Gate voltage tunable second harmonic generation in monolayer and bilayer black phosphene. Phys. Rev. B 113, 045408 (2026) (Editors’ Suggestion).
7. Z. Gong, Y. Bao, Y. Shan, X. Xin, D. Fan, Z. Shi, W. Wang, K. Chang, Y. Song, J. L. Cheng. Thickness-Dependent Raman Spectroscopy Study of m-MoO2 2D Flakes. 42, 2, 211-217 (2026). (In Chinese)
8. S. Lyu, A. Wei, Y. Zhang, K. Chang, L. Wang*. Proposal of Nanometer-Resolved Photoluminescence Imaging with a Single-Molecular Probe Attached to the Tip in STM-Based Plasmon Picocavity. J Phys. Chem. C 129, 48, 21428-21433 (2025).
9. K. Chang*, M. Zubair, J. L. Cheng*, W-K Tse*. Second harmonic generation in topological insulators under quantizing magnetic fields. Phys. Rev. B 111, 205408 (2025).
10. K. Chang*, Y. Song, J. L. Cheng*. Harmonic generation of graphene quantum dots in the Hartree-Fock approximation. Phys. Rev. B 112, 155420 (2025).
11. D. Yang, J. Lai, Z. Fan, S. Wang, K. Chang, L. Meng, J. Cheng*, D. Sun*. Dimensionality-enhanced mid-infrared light vortex detection based on multilayer graphene. Light Sci. Appl. 14:116 (2025).
12. Y. Song, H. Zhang, W. Zhong, M. Liu, W. Wang, J. Jing, L. Qi, Z. Gong, K. Chang, R. Leng, Y. Wang, S. Li, X. Zhao, Z. Lang, Y. Shan*, W. Xin*, J. Cheng*. Phase Identification of Layered GaS by Polarization-Dependent Angle-Resolved Oblique Incident Second Harmonic Generation. Nano Lett. 25, 5770−5777 (2025).
13. Z. Zheng, K. Chang*, J. L. Cheng*. Gate voltage induced injection and shift currents in AA- and AB-stacked bilayer graphene. Phys. Rev. B 108, 235401 (2023).
14. Y. Song, Y. Shan*, W. Wang, K. Chang, Z. Zheng, Z. Shi, D. Li, J. L. Cheng*. Second Harmonic Generation in Exfoliated Few-Layer ReS2. Adv. Opt. Mater. 2300111 (2023).
15. K. Chang*, Z. Zheng, J. E. Sipe, J. L. Cheng*. Theory of optical activity in doped systems with application to twisted bilayer graphene. Phys. Rev. B 106, 24, 245405 (2022).
16. S. Lyu, Y. Zhang*, Y. Zhang, K. Chang, G. Zheng, and L. Wang*. Picocavity controlled subnanometer resolved single molecule fluorescence imaging and mollow triplets. J. Phys. Chem. C,126,11129 (2022).
17. K. Chang, J. Gao, L. Wang*. Theory of plasmon enhanced molecular absorption: effects of plasmon hybridization due to multiple metal nano-particle arrangement. Org. Electron. 32, 83 (2016).
18. J. Gao, K. Chang, L. Wang. Theoretical study of photoinduced charge transfer in molecule and multi-metalnanoparticles system. Acta Phys. Sin. 64,147303 (2015). (In Chinese)
19. L. Wang, K. Chang. Study on electron transfer in a heterogeneous system using a density matrix theory approach. Acta Phys. Sin. 63,137302 (2014). (In Chinese)
科研项目
1. 国家自然科学基金重点项目,范德瓦尔斯界面诱导的非线性光学响应及多场调控,320万,参与。
2. 国家自然科学基金面上项目:可片上集成的中红外波段轨道角动量直接光电探测芯片的关键技术研究,200万,参与。
3. 国家自然科学基金面上项目:分子与半导体界面的电荷分离动力学理论研究,61万,参与。
