Stable single-mode operation of a distributed feedback quantum cascade laser integrated with a distributed Bragg reflector

Feng-Min Cheng; Zhi-Wei Jia; Jin-Chuan Zhang; Ning Zhuo; Shen-Qiang Zhai; Li-Jun Wang; Jun-Qi Liu; Shu-Man Liu; Feng-Qi Liu; Zhan-Guo Wang

doi:10.1364/PRJ.5.000320

Journals >Photonics Research >Volume 5 >Issue 4 >Page 320 > Article

Photonics Research
Vol. 5, Issue 4, 320 (2017)

Stable single-mode operation of a distributed feedback quantum cascade laser integrated with a distributed Bragg reflector

Feng-Min Cheng^1、2、3, Zhi-Wei Jia^1、2、3, Jin-Chuan Zhang^{1、2、3、*}, Ning Zhuo^1、2、3, Shen-Qiang Zhai^1、2、3, Li-Jun Wang^1、2、3, Jun-Qi Liu^1、2、3, Shu-Man Liu^1、2、3, Feng-Qi Liu^{1、2、3、4}, and Zhan-Guo Wang^1、2、3

Author Affiliations

¹Key Laboratory of Semiconductor Materials Science, Institute of Semiconductors, Chinese Academy of Sciences, Beijing, China

²Beijing Key Laboratory of Low Dimensional Semiconductor Materials and Devices, Beijing 100083, China

³College of Materials Science and Opto-Electronic Technology, University of Chinese Academy of Sciences, Beijing 101408, China

⁴e-mail: fqliu@semi.ac.cn

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DOI: 10.1364/PRJ.5.000320 Cite this Article Set citation alerts

Feng-Min Cheng, Zhi-Wei Jia, Jin-Chuan Zhang, Ning Zhuo, Shen-Qiang Zhai, Li-Jun Wang, Jun-Qi Liu, Shu-Man Liu, Feng-Qi Liu, Zhan-Guo Wang. Stable single-mode operation of a distributed feedback quantum cascade laser integrated with a distributed Bragg reflector[J]. Photonics Research, 2017, 5(4): 320 Copy Citation Text

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Fig. 1. Device structure of the DFB QCL integrated with a DBR.

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(a) Transmission spectrum of the uniform grating. The inset shows the detail near the Bragg wavelength. (b) The transmission spectrum of the uniform sampled grating. (c) The transmission spectrum of the uniform sampled grating with the EPS of the λ/4. The inset displays the detail of the positive first-order mode. (d) The blue line is the transmission spectrum of the uniform sampled grating with the EPS of the λ/4, and the red line is the reflection spectrum of the DBR section of the DFB QCL integrated with a DBR.

Fig. 2. (a) Transmission spectrum of the uniform grating. The inset shows the detail near the Bragg wavelength. (b) The transmission spectrum of the uniform sampled grating. (c) The transmission spectrum of the uniform sampled grating with the EPS of the λ/4. The inset displays the detail of the positive first-order mode. (d) The blue line is the transmission spectrum of the uniform sampled grating with the EPS of the λ/4, and the red line is the reflection spectrum of the DBR section of the DFB QCL integrated with a DBR.

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Fig. 3. (a) Emission spectra of the laser without DBR section at 20°C for different currents of 500–580 mA in a step of 40 mA. (b) The emission spectra of the laser with the DBR section at 1.1Ith and 1.25Ith current. (c) The emission spectra of the laser with the DBR section at 20°C for different currents of 500–700 mA in a step of 40 mA. (d) The emission spectra of the laser with the DBR section at 1.1Ith for different heat-sink temperatures of 10–40°C in a step of 10°C. The inset shows the linear tuning characteristics of the wavelength with temperature.

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Fig. 4. P-I characteristics of the lasers as a function of the injection current at pulsed operation at 20°C. The red line shows the P‐I characteristic of the laser without DBR section. The black line displays the P‐I characteristic of the laser with DBR section.

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