Purely Gain-Coupled Distributed-Feedback Bragg Semiconductor Laser Diode Emitting at 770 nm

The transition lines of Mg, K, Fe, Ni, and other atoms lie near 770 nm, therefore, this spectral region is important for helioseismology, solar atmospheric studies, the pumping of atomic clocks, and laser gyroscopes. However, there is little research on distributed-feedback (DFB) semiconductor lasing at 770 nm. In addition, the traditional DFB semiconductor laser requires secondary epitaxy or precision grating preparation technologies. In this study, we demonstrate an easily manufactured, gain-coupled DFB semiconductor laser emitting at 770 nm. Only micrometer scale periodic current injection windows were used, instead of nanoscale grating fabrication or secondary epitaxy. The periodically injected current assures the device maintains single longitudinal mode working in the unetched Fabry–Perot cavity under gain coupled mechanism. The maximum continuous-wave output power reached was 116.3 mW at 20 °C, the maximum side-mode-suppression ratio (SMSR) was 33.25 dB, and the 3 dB linewidth was 1.78 pm.

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Sampled grating distributed feedback (SG DFB) semiconductor laser diode

Optics & Laser Technology ◽

10.1016/j.optlastec.2006.03.002 ◽

2007 ◽

Vol 39 (4) ◽

pp. 754-757

Author(s):

S.N. Mohammad

Keyword(s):

Semiconductor Laser ◽

Laser Diode ◽

Distributed Feedback ◽

Semiconductor Laser Diode ◽

Sampled Grating ◽

Dfb Semiconductor Laser

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Theorical analysis of a monolithic all-active three-section semiconductor laser

Photonics Letters of Poland ◽

10.4302/plp.v9i4.785 ◽

2017 ◽

Vol 9 (4) ◽

pp. 131 ◽

Cited By ~ 1

Author(s):

Mohammed Mehdi Bouchene ◽

Rachid Hamdi ◽

Qin Zou

Keyword(s):

Semiconductor Laser ◽

Semiconductor Lasers ◽

Continuous Wave ◽

Laser Diodes ◽

Optical Power ◽

Longitudinal Mode ◽

Distributed Feedback ◽

Hole Burning ◽

Spatial Hole Burning ◽

Dfb Laser

We propose a novel semiconductor laser structure. It is composed of three cascaded active sections: a Fabry-Pérot laser section sandwiched between two gain-coupled distributed feedback (DFB) laser sections. We have modeled this multi-section structure. The simulation results show that compared with index- and gain-coupled DFB lasers, a significant reduction in the longitudinal spatial-hole burning can be obtained with the proposed device, and that this leads to a stable single longitudinal mode operation at relatively high optical power with a SMSR exceeding 56dB. Full Text: PDF ReferencesL.A. Coldren, "Monolithic tunable diode lasers", IEEE J. Select. Topics Quant. Electron. 6, 988 (2000) CrossRef O. Kjebon, R. Schatz, S. Lourdudoss, S. Nilsson, B. Stalnacke, L. Backbom, "30 GHz direct modulation bandwidth in detuned loaded InGaAsP DBR lasers at 1.55 [micro sign]m wavelength", Electron. Lett. 33(6), 488 (1997). CrossRef N. Kim, J. Shin, E. Sim, C.W. Lee, D.-S. Yee, M.Y. Jeon, Y. Jang, K.H. Park, "Monolithic dual-mode distributed feedback semiconductor laser for tunable continuous-wave terahertz generation", Opt. Expr. 17(16), 13851 (2009). CrossRef M.J. Wallace, R. ORreilly Meehan, R.R Enright, F. Bello, D. Mccloskey, B. Barabadi, E.N. Wang, J.F. Donegan, "Athermal operation of multi-section slotted tunable lasers", Opt. Expr. 25(13), 14426 (2017). CrossRef J.E. Carroll, J.E.A. Whiteaway, R.G.S. Plumb, "Distributed Feedback Semiconductor Lasers", Distributed feedback semiconductor lasers (IEE and SPIE, 1998). CrossRef H. Ghafour-Shiraz, Distributed Feedback Laser Diodes and Optical Tunable Filters (Wiley, 2003). CrossRef D.D. Marcenac, Ph.D dissertation (University of Cambridge, 1993). DirectLink L.M. Zhang, J.E. Carroll, C. Tsang, "Dynamic response of the gain-coupled DFB laser", IEEE J. Quant. Electr. 29, 1722 (1993). CrossRef W. Li, W.-P. Huang, X. Li, J. Hong, "Multiwavelength gain-coupled DFB laser cascade: design modeling and simulation", IEEE J. Quant. Electro. 36(10), 1110 (2000). CrossRef B.M. Mehdi, H. Rachid, in Proc. 3rd Intern. Conf. on Embedded Systems in Telecomm. and Instrument., Annaba, Algeria (2016). DirectLinkC. Henry, "Theory of the linewidth of semiconductor lasers", IEEE J.Quant. Electr. QE-18, 259 (1982). CrossRef K. Takaki, T. Kise, K. Maruyama, N. Yamanaka, M. Funabashi, A. Kasukawa, "Reduced linewidth re-broadening by suppressing longitudinal spatial hole burning in high-power 1.55-/spl mu/m continuous-wave distributed-feedback (CW-DFB) laser diodes", IEEE J. Quant. Electr. 39, 1060 (2003) CrossRef

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High-Power Single-Longitudinal-Mode DFB Semiconductor Laser Based on Sampled Moiré Grating

IEEE Photonics Technology Letters ◽

10.1109/lpt.2019.2906562 ◽

2019 ◽

Vol 31 (10) ◽

pp. 751-754 ◽

Cited By ~ 4

Author(s):

Shengping Liu ◽

Hao Wu ◽

Yuechun Shi ◽

Bocang Qiu ◽

Rulei Xiao ◽

...

Keyword(s):

Semiconductor Laser ◽

High Power ◽

Longitudinal Mode ◽

Single Longitudinal Mode ◽

Dfb Semiconductor Laser

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Monolithic dual-mode distributed feedback semiconductor laser for tunable continuous-wave terahertz generation

Optics Express ◽

10.1364/oe.17.013851 ◽

2009 ◽

Vol 17 (16) ◽

pp. 13851 ◽

Cited By ~ 91

Author(s):

Namje Kim ◽

Jaeheon Shin ◽

Eundeok Sim ◽

Chul Wook Lee ◽

Dae-Su Yee ◽

...

Keyword(s):

Semiconductor Laser ◽

Continuous Wave ◽

Distributed Feedback ◽

Terahertz Generation ◽

Dual Mode

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Simulation of the Optimized Structure of a Laterally Coupled Distributed Feedback (LC-DFB) Semiconductor Laser Above Threshold

Engineering, Technology & Applied Science Research ◽

10.48084/etasr.376 ◽

2013 ◽

Vol 3 (5) ◽

pp. 522-525

Author(s):

M. Seifouri ◽

A. Faraji

Keyword(s):

Active Region ◽

Semiconductor Laser ◽

Structural Properties ◽

Output Power ◽

Structural Parameters ◽

Distributed Feedback ◽

Ridge Width ◽

Bragg Frequency ◽

Dfb Semiconductor Laser

In this paper, the laterally coupled distributed feedback semiconductor laser is studied. In the simulations performed, variations of structural parameters such as the grating amplitude a, the ridge width W, the thickness of the active region d, and other structural properties are considered. It is concluded that for certain values of structural parameters, the laser maintains the highest output power, the lowest distortion Bragg frequency δL and the smallest changes in the wavelength λ. Above threshold, output power more than 40mW and SMSR values greater than 50 dB were achieved.

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