Dr. Cheng Wang

Semiconductor Optoelectronics and Dynamics Group

Journal Papers

2018

- 24-J. Duan, X. G. Wang, Y. G. Zhou, C. Wang*, and F. Grillot, "Carrier-noise enhanced relative intensity noise of quantum dot lasers," IEEE J. Quantum Electron. 54, 2001407 (2018).
- 23-Y. G. Zhou, X. Y. Zhao, C. F. Cao, Q. Gong, and C. Wang*, "High optical feedback tolerance of InAs/GaAs quantum dot lasers on germanium," Opt. Express 26, 28131 (2018).
- 22-X. G. Wang, B. B. Zhao, F. Grillot, and C. Wang*, "Frequency noise suppression of optical injection-locked quantum cascade lasers," Opt. Express 26, 15167 (2018).
- 21-J. Duan, H. Huang, Z. G. Lu, P. J. Poole, C. Wang, and F. Grillot, "Narrow spectral linewidth in InAs/InP quantum dot distributed feedback lasers," Appl. Phys. Lett. 112, 121102 (2018).
- 20-X. G. Wang, F. Grillot and C. Wang*, "Rate equation modeling of the frequency noise and the intrinsic spectral linewidth in quantum cascade lasers," Opt. Express 26, 2325 (2018).

2017

- 19-Y. G. Zhou, C. Zhou, C. F. Cao, J. B. Du, Q. Gong, and C. Wang*, "Relative intensity noise of InAs quantum dot lasers epitaxially grown on Ge," Opt. Express 25, 28817 (2017).

2016

- 18-C. Wang, J. -P. Zhuang, F. Grillot, and S. -C. Chan, "Contribution of off-resonant states to the phase noise of quantum dot lasers," Opt. Express 24, 29872 (2016).
- 17-
**[Book Chapter]**J. Even, C. Wang, and F. Grillot, "From basic physical properties of InAs/InP quantum dots to state-of-the-art lasers for 1.55 µm optical. communications: an overview," in*Semiconductor Nanocrystals and Metal Nanoparticles: Physical Properties and Device Applications*(CRC Press, 2016). - 16-C. Wang, K. Schires, M. Osiński, P. J. Poole, and F. Grillot, "Thermally insensitive determination of the linewidth broadening factor in nanostructured semiconductor lasers using optical injection locking," Nature Scientific Reports 6, 27825 (2016).
- 15-C. Wang, R. Raghunatahn, K. Schires, S. –C. Chan, L. F. Lester, and F. Grillot, “Optically injected InAs/GaAs quantum dot laser for tunable photonic microwave generation,” Opt. Lett. 41, 1153 (2016).

2015

- 14-C. Wang, M. E. Chabi, H. M. Huang, D. Erasme, P. J. Poole, J. Even, and F. Grillot, “Frequency-dependent linewidth enhancement factor of optical injection-locked quantum dot/dash laser,” Opt. Express 23, 21761 (2015).
- 13-I. Aldaya, C. Gosset, C. Wang, G. Campuzano, F. Grillot, and G. Castanon, “Periodic and aperiodic pulse generation using optically injected DFB laser,” IET Electron. Lett. 51, 280 (2015).

2014

- 12-C. Wang, M. Osiński, J. Even, and F. Grillot, “Phase-amplitude coupling characteristics in directly modulated quantum dot lasers,” Appl. Phys. Lett. 105, 221114 (2014).
- 11-C. Wang, B. Lingnau, K. Lüdge, J. Even, and F. Grillot, “Enhanced dynamic performance of quantum dot semiconductor lasers operating on the excited state,” IEEE J. Quantum Electron. 50, 723 (2014).
- 10-C. Wang, F. Grillot, F. Y. Lin, I. Aldaya, T. Batte, C. Gosset, E. Decerle, and J. Even, “Nondegenerate four-wave mixing in a dual-mode injection-locked InAs/InP(100) nanostructure laser,” IEEE Photon. Journal 6, 1500408 (2014).
- 9-C. Wang, F. Grillot, and J. Even, “Analysis of frequency chirp of self-injected nanostructure semiconductor lasers,” IET Optoelectron. 8, 51 (2014).
- 8-C. Gosset, I. Aldaya, C. Wang, H. Huang, X. You, J. Even, G. Campuzano, and F. Grillot, “Self-referenced technique for monitoring and analyzing the non-linear dynamics of semiconductor lasers,” Opt. Express 22, 16528 (2014).

2013

- 7-C. Wang, F. Grillot,V. I. Kovanis, J. D. Bodyfelt, and J. Even, “Modulation properties of optically injection-locked quantum cascade lasers,” Opt. Lett. 38, 1975 (2013).
- 6-C. Wang, F. Grillot, V. Kovanis, and J. Even, “Rate equation analysis of injection-locked quantum cascade lasers,” J. Appl. Phys. 113, 063104 (2013).
- 5-F. Grillot, C. Wang, N. A. Naderi, and J. Even, “Modulation properties of self-injected quantum-dot semiconductor diode lasers,” IEEE J. Sel. Topics in Quantum Electron.19, 1900812 (2013).

2012

- 4-C. Wang, F. Grillot, and J. Even, “Impacts of wetting layer and excited state on the modulation response of quantum-dot lasers,” IEEE J. Quantum Electon. 48, 1144 (2012).
- 3-X. Yu, C. Wang*, F. Chen, R. P. Yan, Y. F. Ma, and X. D. Li, “Performance improvement of high repetition rate electro-optical cavity-dumping Nd:GdVO4 laser,” Appl. Phys. B 106, 309 (2012).

2011

2010

2011

- 2-X. Yu, C. Wang*, F. Chen, R. P. Yan, Y. F. Ma, X. D. Li, and J. B. Peng, “Comparison of electro-optical and acousto-optical Q-switched, high repetition rate Nd:GdVO4 laser,” Laser Phys. 21, 442 (2011).

2010

- 1-X. Yu, C. Wang*, F. Chen, R. P. Yan, X. D. Li, J. B. Peng, and J. H. Yu, “High repetition rate, high peak power acousto-optical Q-switched 946 nm Nd:YAG laser,” Laser Phys. 20, 1783 (2010).

Conference Papers

2018

- 35-Xing-Guang Wang and Cheng Wang, "Noise of quantum cascade lasers with optical feedback," ISPALD, Hong Kong, China, December, 2018.
- 34-J. Duan, X. G. Wang, Y. G. Zhou, C. Wang, and F. Grillot, "Relative intensity noise properties of quantum dot lasers," Proc. of SPIE (2018).
- 33-Y. G. Zhou, C. F. Cao, J. Y. Yan, Q. Gong, and C. Wang*, "Temperature and optical feedback sensitivity of the relative intensity noise of epitaxial quantum dot lasers on Ge," CLEO-PR, Hong Kong, July, 2018.
- 32-X. G. Wang, B. B. Zhao, and C. Wang*, "Frequency noise reduction of injection-locked quantum cascade lasers," CLEO-PR, Hong Kong, July (2018).
- 31-J. Duan, X. G. Wang, Y. G. Zhou, C. Wang, and F. Grillot, "Contribution des etas non-resonants au bruit relatif d’intensite dans les lasers à ilots quantiques," Optique, Toulouse, France, July, 2018.
- 30-Y. G. Zhou and C. Wang*, "Pulse-amplitude modulation of optical injection-locked quantum-dot lasers," Proc. of SPIE 1052606 (2018).
- 29-J. Duan, H. Huang, K. Schires, P. J. Poole, C. Wang, and F. Grillot, "Temperature dependence of spectral linewidth of InAs/InP quantum dot distributed feedback lasers," Proc. of SPIE 10553, 105530J (2018).

2017

- 28-C. Wang, Y. G. Zhou, Q. Gong, C. F. Cao, J. B. Du, and C. Zhou, "Effects of epitaxial defect on the optical noise of InAs/GaAs quantum dot lasers monlithically grown on germanium," ISPALD, Paris, France, November, 2017.
- 27-X. G. Wang and C. Wang*, "Langevin approach analysis of the frequency noise in quantum cascade lasers," Frontiers in Optics, Washington, US, September, 2017.
- 26-C. Wang, "Modeling of period one oscillations in optically injected quantum cascade lasers," CLEO-PR, Singapore, August, 2017.
- 25-C. Zhou, Y. G. Zhou, J. B. Du, C. F. Cao, Q. Gong, and C. Wang*, "Relative intensity noise of an InAs/GaAs quantum dot laser epitaxially grown on germanium," CIOP, Harbin, July, 2017.

2016

- 24-C. Wang and F. Grillot, "Low phase noise quantum dot lasers for coherent communication networks," ACP Conference, Paper AF2A.55, Wuhan, China, November, 2016.
- 23-C. Wang, J. P. Zhuang, F. Grillot, and S. Z. Chan, "Linewidth broadening factor in quantum dot lasers extracted by optical noise analysis," IS-PALD, Hsinchu, Taiwan, September, 2016.
- 22-C. Wang, “New features of linewidth broadening factor in quantum dot lasers,” Light Conference (Young Scientist Forum), Changchun, China, July, 2016.

2015

- 21-C. Wang, Kevin Schires, Marek Osiński, Philip J. Poole, Jacky Even, and Frédéric Grillot, “A novel method for extracting the linewidth broadening factor of semiconductor lasers,” Frontiers in Optics/Laser Science Conference (FiO/LS), San Jose, California, USA, October, 2015.
- 20-C. Wang, M. Osiński, K. Schires, J. Even, and F. Grillot, “Modulation-frequency dependence of the phase-amplitude coupling in quantum dot lasers,” CLEO, San Jose, CA, May, 2015.
- 19-C. Wang, M. Osiński, J. Even, and F. Grillot, “Modulation-frequency dependent linewidth enhancement factor of quantum dot lasers,” SIOE, Cardiff, Wales, April, 2015.
- 18-C. Wang, M. Gioannini, I. Montrosset, J. Even, and F. Grillot, “Influence of inhomogeneous broadening on the dynamics of quantum dot lasers,” Proc. of SPIE 9357, 93570L, (2015).

2014

- 17-C. Wang, J. Even, and F. Grillot, “Near-threshold relaxation dynamics of a quantum dot laser,” Proc. of SPIE 9134, 913404 (2014).
- 16-C. Wang, F. Grillot, V. I. Kovanis, J. D. Bodyfelt, and J. Even, “Rate Equation Analysis of Frequency Chirp in Optically Injection-Locked Quantum Cascade Lasers,” Proc. of SPIE 8980, 898014 (2014).
- 15-C. Wang, F. Grillot, I. Aldaya, C. Gosset, T. Batte, E. Decerle, and J. Even, “Nondegenerate Four-Wave Mixing in a Dual-Mode Injection Locked InAs/InP(100) Quantum Dot Laser,” Proc. of SPIE 8980, 89801K (2014).
- 14-C. Wang, M. E. Chaibi, B. Lingnau, D. Erasme, K. Lüdge, P. Poole, J. G. Provost, J. Even, and F. Grillot, “Phase-amplitude coupling of optically injected nanostructure semiconductor lasers,” IEEE Photonics Conference (IPC), San Diego, California USA, October, 2014.
- 13-C. Wang, M. E. Chaibi, B. Lingnau, D. Erasme, K. Lüdge, P. Poole, J. G. Provost, J. Even, and F. Grillot, “Amplitude modulation and frequency chirp of an injection-locked quantum dash semiconductor laser,” IEEE International Semiconductor Laser Conference (ISLC), Palma de Mallorca, Spain, September, 2014.
- 12-C. Wang, B. Lingnau, E. Schöll, K. Lüdge, J. Even, F. Grillot, “High performance excited-state nanostructure lasers---modulation response, frequency chirp and linewidth enhancement factor,” CLEO: Applications and Technology, San Jose, California, United States, June, 2014.

2013

- 11-C. Wang, F. Grillot, and J. Even, “Intensity modulation response of injection-locked quantum cascade lasers,” Proc. of SPIE 8619, 86191Q (2013).
- 10-C. Wang, F. Grillot, and J. Even, “Impacts of carrier capture and relaxation rates on the modulation response of injection-locked quantum dot lasers,” Proc. of SPIE 8619, 861908 (2013).
- 9-C. Wang, F. Grillot, and J. Even, “Nonlinear dynamics and modulation properties of optically injected quantum cascade lasers,” CLEO/Europe, Munich, Germany, May, 2013.
- 8-C. Wang, F. Grillot, and J. Even, “From basic physical properties of InAs/InP quantum dots to state of the art semi-empirical modelling of 1.55 μm directly modulated QD lasers: an overview,” Semiconductor and Integrated Optoelectronics (SIOE), Cardiff, Wales, April, 2013.
- 7-C. Wang, F. Grillot, and J. Even, “Self-injected quantum dot semiconductor lasers,” Semiconductor and Integrated Optoelectronics (SIOE), Cardiff, Wales, April, 2013.

2012

- 6-C. Wang, F. Grillot, and J. Even, “Carrier escape from ground state and non-zero resonance frequency at low bias powers for semiconductor quantum-dot lasers,” Proc. of SPIE 8432, 843225 (2012).
- 5-C. Wang, F. Grillot, and J. Even, “Controlling the pre-resonance frequency dip in the modulation response of injection-locked quantum dot lasers,” Nonlinear Dynamics in Semiconductor Lasers (NDSL), Berlin, Germany, September, 2012.
- 4-C. Wang, F. Grillot, and J. Even, “Modelling the gain compression effects in semiconductor quantum-dot lasers through a new modulation transfer function,” IEEE Photonics Conference (IPC), CA, USA, September, 2012.
- 3-C. Wang, F. Grillot, and J. Even, “Nouvelle formulation de la function de transfer d’un laser à nanostructures quantiques pour les applications à la modulation haut-debit et aux phenomenes microscopiques non-lineaires,” Journées Nationales d'Optique Guidée (JNOG), Lyon, France, July, 2012.
- 2-C. Wang, F. Grillot, and J. Even, “Modulation response of semiconductor quantum dot lasers,” Semiconductor and Integrated Optoelectronics (SIOE), Cardiff, Wales, April, 2012.

2010

- 1-X. Yu, C. Wang, F. Chen, R. P. Yan, X. D. Li, and J. H. Yu, “100 kHz electro-optical Q-switched Nd:GdVO4 Laser,” ASOMT&CRST, Harbin, China, July, 2010.