Wavelength Scaling of Widely-Tunable Terahertz Quantum-Cascade Metasurface Lasers

Kim, Anthony D.; Curwen, Christopher A.; Wu, Yu Sheng; Reno, John L.; Addamane, Sadhvikas; Williams, Benjamin S.

doi:10.1109/jmw.2022.3224640

“…Because the metasurface has a large surface-radiating area (millimeter scale), it couples efficiently to fundamental Gaussian modes of the external cavity, resulting in a high-quality output beam. Additionally, the lasing frequency is determined by the length of the external cavity, which can be mechanically tuned over broad bandwidths [10,11]. One remaining aspect that we investigate in this study is the frequency stability and phase-locking of the QC-VECSEL.…”

Section: Introductionmentioning

confidence: 99%

Phase locking of THz QC-VECSELs to a microwave reference

Curwen¹,

Kawamura²,

Hayton³

et al. 2023

Preprint

0

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<p>High resolution frequency study and phase-locking have been performed on terahertz quantum-cascade vertical-external-cavity surface-emitting-lasers at 2.5 THz and 3.4 THz. A subharmonic diode mixer is used to downconvert the THz signal to a gigahertz intermediate frequency (IF). Feedback from reflections at the mixer are observed to have a strong influence on the free-running QC-VECSEL frequency stability as a result of efficient coupling to free-space compared to more typical ridge waveguide lasers. Instabilities in feedback result in free-running linewidths of tens of MHz, and at times >100 MHz. The QC-VECSEL IF signal is phase locked to a 100 MHz reference using the bias on the device as a means of error correction. Between 90-95% of the QC-VECSEL signal is locked within 2 Hz of the multiplied RF reference, and amplitude fluctuations on the order of 1-10% are observed, depending on the bias point of the QC-VECSEL. The bandwidth of the locking loop is ~1 MHz. Many noise peaks in the IF signal corresponding to mechanical resonances in the 10 Hz-10 kHz range are observed. These peaks are generally -30 to -60 dB below the main tone, and are below the phase noise level of the multiplied RF reference which ultimately limits the phase noise of the locked QC-VECSEL.</p>

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“…Because the metasurface has a large surface-radiating area (millimeter scale), it couples efficiently to fundamental Gaussian modes of the external cavity, resulting in a high-quality output beam. Additionally, the lasing frequency is determined by the length of the external cavity, which can be mechanically tuned over broad bandwidths [10,11]. One remaining aspect that we investigate in this study is the frequency stability and phase-locking of the QC-VECSEL.…”

Section: Introductionmentioning

confidence: 99%

Phase locking of THz QC-VECSELs to a microwave reference

Curwen¹,

Kawamura²,

Hayton³

et al. 2023

Preprint

0

View full text Add to dashboard Cite

<p>High resolution frequency study and phase-locking have been performed on terahertz quantum-cascade vertical-external-cavity surface-emitting-lasers at 2.5 THz and 3.4 THz. A subharmonic diode mixer is used to downconvert the THz signal to a gigahertz intermediate frequency (IF). Feedback from reflections at the mixer are observed to have a strong influence on the free-running QC-VECSEL frequency stability as a result of efficient coupling to free-space compared to more typical ridge waveguide lasers. Instabilities in feedback result in free-running linewidths of tens of MHz, and at times >100 MHz. The QC-VECSEL IF signal is phase locked to a 100 MHz reference using the bias on the device as a means of error correction. Between 90-95% of the QC-VECSEL signal is locked within 2 Hz of the multiplied RF reference, and amplitude fluctuations on the order of 1-10% are observed, depending on the bias point of the QC-VECSEL. The bandwidth of the locking loop is ~1 MHz. Many noise peaks in the IF signal corresponding to mechanical resonances in the 10 Hz-10 kHz range are observed. These peaks are generally -30 to -60 dB below the main tone, and are below the phase noise level of the multiplied RF reference which ultimately limits the phase noise of the locked QC-VECSEL.</p>

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