Waveguiding and dispersion properties of interband cascade laser frequency combs

Mid-infrared semiconductor lasers have emerged as indispensable compact coherent sources for military and commercial applications. While much of the historical emphasis has been on maximizing the output power and/or spectral purity, a recent new focus has been on engineering these lasers to operate as optical frequency combs (OFCs) for broadband real-time spectroscopy. In particular, the combination of low-drive-power and broad gain bandwidth has made interband cascade laser (ICL) OFCs an attractive complement to quantum cascade laser OFCs operating at longer wavelengths. Moreover, ICL combs can potentially be incorporated into fully-integrated dual-comb spectrometers that employ fast, room-temperature IC photodetectors processed on the same chip. However, the high refractive index of the ICL’s GaSb substrate poses some challenges to the optical waveguiding. Because the modal index is considerably lower than that of the substrate, the optical field can penetrate the bottom cladding layer and leak into the GaSb, inducing wavelength-dependent interference that modifies the gain and group velocity dispersion (GVD) profiles. Even when the effect on lasing threshold is small, the comb properties can be adversely affected. Using the sub-threshold Fourier transform technique, we studied ICL combs with various ridge widths, substrate thicknesses, and center wavelengths. This allowed us to evaluate the effects of modal leakage on the GVD. We find that the resonant nature of the substrate modes induces oscillations, which affect both the spectral bandwidth and the phase-locking properties above threshold. Strategies to mitigate the GVD’s undesired and unpredictable spectral variation will be presented.

[1]  I. Vurgaftman,et al.  Mid-infrared dual-comb spectroscopy with room-temperature bi-functional interband cascade lasers and detectors , 2020 .

[2]  John H. Marsh,et al.  Longitudinal mode grouping in InGaAs/GaAs/AlGaAs quantum dot lasers: origin and means of control , 1998 .

[3]  Yao-Ming Mu,et al.  Interband cascade lasers , 2000, Photonics West - Optoelectronic Materials and Devices.

[4]  Yves Bidaux,et al.  Dual comb operation of λ ̃ 8.2 μm quantum cascade laser frequency comb with 1 W optical power , 2017 .

[5]  Manijeh Razeghi,et al.  Shortwave quantum cascade laser frequency comb for multi-heterodyne spectroscopy , 2018 .

[6]  J. Faist,et al.  Measurement of semiconductor laser gain and dispersion curves utilizing Fourier transforms of the emission spectra , 1999, IEEE Photonics Technology Letters.

[7]  Jérôme Faist,et al.  On-chip mid-infrared and THz frequency combs for spectroscopy , 2019, Applied Physics Letters.

[8]  Rui Q. Yang,et al.  Type-II and type-I interband cascade lasers , 1996 .

[9]  Gottfried Strasser,et al.  Monolithic frequency comb platform based on interband cascade lasers and detectors , 2018, Optica.

[10]  Igor Vurgaftman,et al.  Near-infrared frequency comb generation in mid-infrared interband cascade lasers. , 2019, Optics letters.

[11]  A. Bismuto,et al.  Plasmon-enhanced waveguide for dispersion compensation in mid-infrared quantum cascade laser frequency combs. , 2017, Optics letters.

[12]  M. Beck,et al.  Coupled‐Waveguides for Dispersion Compensation in Semiconductor Lasers , 2017, 1711.09116.

[13]  Sergei V. Zaitsev,et al.  Spectral and dynamic properties of InAs-GaAs self-organized quantum-dot lasers , 1999 .

[14]  M. Beck,et al.  Heterogeneous terahertz quantum cascade lasers exceeding 1.9 THz spectral bandwidth and featuring dual comb operation , 2016, 1612.07594.

[15]  V P Konyaev,et al.  Waveguiding properties of heterolasers based on InGaAs/GaAs strained quantum-well structures and characteristics of their gain spectra , 1994 .

[16]  Chul Soo Kim,et al.  Mid-IR Type-II Interband Cascade Lasers , 2011, IEEE Journal of Selected Topics in Quantum Electronics.

[17]  Rui Q. Yang Infrared laser based on intersubband transitions in quantum wells , 1995 .

[18]  Peter Michael Smowton,et al.  Spectral analysis of InGaAs/GaAs quantum-dot lasers , 1999 .

[19]  Qing Hu,et al.  Dispersion dynamics of quantum cascade lasers , 2016 .

[20]  Gregory Belenky,et al.  Experimental study of the optical gain and loss in InAs/GaInSb interband cascade lasers , 2003 .

[21]  Charles D. Merritt,et al.  Multiheterodyne spectroscopy using interband cascade lasers , 2017, 1709.03042.

[22]  Manijeh Razeghi,et al.  High efficiency quantum cascade laser frequency comb , 2017, Scientific Reports.

[23]  William W. Bewley,et al.  Antimonide type-II “W” lasers: growth studies and guided-mode leakage into substrate , 2004 .

[24]  Manijeh Razeghi,et al.  Room temperature terahertz semiconductor frequency comb , 2019, Nature Communications.

[25]  J. Faist,et al.  Room temperature terahertz quantum cascade laser source based on intracavity difference-frequency generation , 2008 .

[26]  Manijeh Razeghi,et al.  Dispersion compensated mid-infrared quantum cascade laser frequency comb with high power output , 2017 .

[27]  William W. Bewley,et al.  Correlating growth conditions with photoluminescence and lasing properties of mid-IR antimonide type II “W” structures , 2004 .

[28]  Qing Hu,et al.  Terahertz laser frequency combs , 2014, Nature Photonics.

[29]  Gerard Wysocki,et al.  Mid-infrared dual-comb spectroscopy with interband cascade lasers. , 2019, Optics letters.

[30]  Mattias Beck,et al.  Dispersion engineering of Quantum Cascade Lasers frequency combs , 2015, 1509.08856.

[31]  Igor Vurgaftman,et al.  Pulsed and CW performance of 7-stage interband cascade lasers. , 2014, Optics express.

[32]  J. Faist,et al.  Mid-infrared frequency comb based on a quantum cascade laser , 2012, Nature.

[33]  William W. Bewley,et al.  Passively mode-locked interband cascade optical frequency combs , 2018, Scientific Reports.