Gong Cheng （龚诚）

Email: gongcheng@nankai.edu.cn

 

教育背景

学士学位, 北京理工大学，光电学院 (2006)

硕士学位, 北京理工大学，光电学院 (2009)

博士学位, 北京理工大学，光电学院 (2014)

博士联合培养，波士顿大学，光电子中心 (2013-2014)

 

工作经历

讲 师, 南开大学, 现代光学研究所 (2014 - 2018)

副教授, 南开大学, 现代光学研究所 (2019 - )

 

研究兴趣

 

微结构器件和太赫兹无损成像

 

主要成果

已经主持两项国家级科研项目，并主持多项企业科研项目。

已经在高水平期刊发表学术论文二十余篇, 包括Optics Letters, Optics Express, J. Phys. D: Appl. Physics等等.

 

 

相关论文：

[01] W. Su, W. Guo, Z. Wang, P. Chen, C. Gong*(龚诚), L. Lin, W. Liu, “Printing flexible terahertz metasurface of optical transparency,” J. Phys. D: Appl. Phys. 52 (2019) 095107. 

[02] C. Gong(龚诚), Z. Dai, M. Zhou, W. Liu, “Method to tune a high-order resonance of metamaterials for broadband,” Optical Materials Express 8(9) (2018) 2768. 

[03] Z. Wang, Y. Zhou, L. Yang, and C. Gong*(龚诚), “Waveguide-based terahertz metamaterial functional components,” J. Phys. D: Appl. Phys. 50 (2017) 375107. 

[04] C. Gong(龚诚), M. Zhan, J, Yang, Z. Wang, H. Liu, Y. Zhao, W. Liu, “Broadband terahertz metamaterial absorber based on sectional asymmetric structures,” Scientific Reports 6(32466), (2016). 

[05] J. Yang, C. Gong*(龚诚), L. Sun, P. Chen, L. Lin, W. Liu, “Tunable reflecting terahertz filter based on chirped metamaterial structure,” Scientific Reports 6 (2016) 38732. 

[06] C. Gong(龚诚), W. Su, Y. Zhang, P. Chen, W. Liu, “An active metamaterials controlled by structured light illumination,” Optik 171 (2018) 204-209. 

[07] S. Li, Z. Dai, X. Gao, T. Zhan, D. Zhao, C. Gong*(龚诚), W. Liu, “Low-loss terahertz waveguide and its imaging application,” J. Infrared Millim. Waves 37 (1) (2019). 

[08] S. Li, Z. Dai, Z. Wang, Q. Su, X. Gao, C. Gong*(龚诚), W. Liu, “A 0.1 THz low-loss 3D printed hollow waveguide,” Optik 176 (2019) 611-616. 

[09] C. Gong(龚诚), Y. Zhao, L. Dong, X. Yu, P. Chen, and W. Liu, "All-optical background subtraction readout method for bimaterial cantilever array sensing," Optics Express, 2015, 23, 20576-20581. 

[10] C. Gong(龚诚), M. Hui, L. Dong, Y. Zhao, X. Yu, and X. Liu, “Optical readout method based on a narrow-strip filter for microcantilever array sensing,” Optics Letters, 2012, 37(7): 1187-1189. 

[11] C. Gong(龚诚), Y. Zhao, L. Dong, M. Hui, X. Yu, and X. Liu, “The tolerable target temperature for bimaterial microcantilever array infrared imaging,” Optics & Laser Technology, 2013, 45 : 545-550. 

[12] C. Gong(龚诚), Y. Zhao, L. Dong, M. Hui, X. Yu, and X. Liu, “Short-wave infrared, medium-wave infrared, and long-wave infrared imaging study for optical readout microcantilever array infrared sensing system ,” Optical Engineering, 2013, 52(2): 026403. 

[13] C. Gong(龚诚), Y. Zhao, L. Dong, M. Hui and X. Yu, “Pixels array matching for optical readout microcantilever array sensing system,” Optik, 2013, 124: 6058-6062. 

[14] X. Hu, C. Gong*(龚诚), D. Ren, "Scaling instantaneous frequency measurement method inspired by hawk's eye," Microwave and optical technology letters, 2015, 57(6):1383-1385. 

[15] T. Yu, X. Zuo, W. Liu, C. Gong*(龚诚), “0.1THz super-resolution imaging based on 3D printed confocal waveguides,” Optics Communications, 2020, 459: 124896.