Single mode terahertz quantum cascade lasers based on distributed Bragg reflector

Hong-Zhou BAI; Shan-Zhi ZANG; Cheng TAN; Kai WANG; Lianghua GAN; Gang-Yi XU

doi:10.11972/j.issn.1001-9014.2023.06.013

Journal of Infrared and Millimeter Waves, Volume. 42, Issue 6, 795(2023)

Single mode terahertz quantum cascade lasers based on distributed Bragg reflector

Hong-Zhou BAI^1,2, Shan-Zhi ZANG^1,2, Cheng TAN^1,2, Kai WANG¹, Lianghua GAN¹, and Gang-Yi XU^1,3、*

¹Key Laboratory of Infrared Imaging Materials and Detectors，Shanghai Institute of Technical Physics，Chinese Academy of Sciences，Shanghai 200083，China

²University of Chinese Academy of Sciences，Beijing 100049，China

³Hangzhou Institute for Advanced Study，University of Chinese Academy of Sciences，Hangzhou 310024，China

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References(29)

[1] Dean P, Shaukat M U, Khanna S P et al. Absorption-sensitive diffuse reflection imaging of concealed powders using a terahertz quantum cascade laser[J]. Optics Express, 16, 5997-6007(2008).

[2] Kim S M, Hatami F, Harris J S et al. Biomedical terahertz imaging with a quantum cascade laser[J]. Applied Physics Letters, 88, 153903(2006).

[3] Sampaolo A, Yu C, Wei T et al. H2S quartz-enhanced photoacoustic spectroscopy sensor employing a liquid-nitrogen-cooled THz quantum cascade laser operating in pulsed mode[J]. Photoacoustics, 21, 100219(2021).

[4] Hor Y L, Federici J F, Wample R L. Nondestructive evaluation of cork enclosures using terahertz/millimeter wave spectroscopy and imaging[J]. Applied Optics, 47, 72-78(2008).

[5] Lee A W M, Qin Q, Kumar S et al. Real-time terahertz imaging over a standoff distance (> 25 meters)[J]. Applied Physics Letters, 89, 141125(2006).

[6] Köhler R, Tredicucci A, Beltram F et al. Terahertz semiconductor-heterostructure laser[J]. Nature, 417, 156-159(2002).

[7] Carroll J E, Whiteaway J, Plumb D et al[M]. Distributed feedback semiconductor lasers(1998).

[8] Kohen S, Williams B S, Hu Q. Electromagnetic modeling of terahertz quantum cascade laser waveguides and resonators[J]. Journal of applied physics, 97, 053106(2005).

[9] Williams B S, Kumar S, Hu Q et al. Distributed-feedback terahertz quantum-cascade lasers with laterally corrugated metal waveguides[J]. Optics letters, 30, 2909-2911(2005).

[10] Kumar S, Williams B S, Qin Q et al. Surface-emitting distributed feedback terahertz quantum-cascade lasers in metal-metal waveguides[J]. Optics Express, 15, 113-128(2007).

[11] Schubert M, Rana F. Analysis of terahertz surface emitting quantum-cascade lasers[J]. IEEE journal of quantum electronics, 42, 257-265(2006).

[12] Xu G, Colombelli R, Khanna S P et al. Efficient power extraction in surface-emitting semiconductor lasers using graded photonic heterostructures[J]. Nature Communications, 3, 1-7(2012).

[13] Xu G, Li L, Isac N et al. Surface-emitting terahertz quantum cascade lasers with continuous-wave power in the tens of milliwatt range[J]. Applied Physics Letters, 104, 091112(2014).

[14] Jin Y, Gao L, Chen J et al. High power surface emitting terahertz laser with hybrid second-and fourth-order Bragg gratings[J]. Nature communications, 9, 1-7(2018).

[15] Zhu H, Zhu H, Wang K et al. Terahertz master-oscillator power-amplifier quantum Cascade laser with controllable polarization[J]. Applied Physics Letters, 117, 021103(2020).

[16] Zhang H, Dunbar L A, Scalari G et al. Terahertz photonic crystal quantum cascade lasers[J]. Optics Express, 15, 16818-16827(2007).

[17] Chassagneux Y, Colombelli R, Maineult W et al. Graded photonic crystal terahertz quantum cascade lasers[J]. Applied Physics Letters, 96, 031104(2010).

[18] Klimont A, Ottomaniello A, Degl’Innocenti R et al. Line-defect photonic crystal terahertz quantum cascade laser[J]. Journal of Applied Physics, 126, 153104(2019).

[19] Xu L, Curwen C A, Hon P W C et al. Metasurface external cavity laser[J]. Applied Physics Letters, 107, 221105(2015).

[20] Xu L, Curwen C A, Reno J L et al. High performance terahertz metasurface quantum-cascade VECSEL with an intra-cryostat cavity[J]. Applied Physics Letters, 111, 101101(2017).

[21] Curwen C A, Reno J L, Williams B S. Broadband continuous single-mode tuning of a short-cavity quantum-cascade VECSEL[J]. Nature Photonics, 13, 855-859(2019).

[22] Hofmann W H, Moser P, Bimberg D. Energy-efficient VCSELs for interconnects[J]. IEEE Photonics Journal, 4, 652-656(2012).

[23] Hofmann W. Evolution of high-speed long-wavelength vertical-cavity surface-emitting lasers[J]. Semiconductor science and technology, 26, 014011(2010).

[24] Coldren L A, Corzine S W, Mashanovitch M L[M]. Diode lasers and photonic integrated circuits(2012).

[25] Mueller G[M]. Intersubband Transitions in Quantum Wells: Physics and Device Applications II(1999).

[26] Faist J[M]. Quantum cascade laser(2013).

[27] Hakki B W, Paoli T L. CW degradation at 300 K of GaAs double‐heterostructure junction lasers. II. Electronic gain[J]. Journal of Applied Physics, 44, 4113-4119(1973).

[28] Williams B S, Kumar S, Callebaut H et al. Terahertz quantum-cascade laser at λ≈100 μm using metal waveguide for mode confinement[J]. Applied Physics Letters, 83, 2124-2126(2003).

[29] Kröll J, Darmo J, Dhillon S S et al. Phase-resolved measurements of stimulated emission in a laser[J]. Nature, 449, 698-701(2007).

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Hong-Zhou BAI, Shan-Zhi ZANG, Cheng TAN, Kai WANG, Lianghua GAN, Gang-Yi XU. Single mode terahertz quantum cascade lasers based on distributed Bragg reflector[J]. Journal of Infrared and Millimeter Waves, 2023, 42(6): 795

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Paper Information

Category: Research Articles

Received: Mar. 12, 2023

Accepted: --

Published Online: Dec. 26, 2023

The Author Email: Gang-Yi XU (gangyi.xu@mail.sitp.ac.cn)

DOI:10.11972/j.issn.1001-9014.2023.06.013

Topics

laser devices and laser physics

Lasers and Laser Optics

Laser physics

laser manufacturing

Instrumentation, Measurement and Metrology