Ultrafast response of harmonic modelocked THz lasers

Wang, Feihu; Pistore, Valentino; Riesch, Michael; Nong, Hanond; Vigneron, P.; Colombelli, R.; Parillaud, O.; Mangeney, J.; Tignon, Jérôme; Jirauschek, Christian; Dhillon, Sukhdeep

doi:10.1038/s41377-020-0288-x

Cited by 52 publications

(24 citation statements)

References 34 publications

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“…At higher I B (between 270 and 320 mA), the lower-frequency AR module crosses threshold. In this range, the QCL operates in an harmonic state, [17,[32][33][34] where the spacing between adjacent modes is 2 f rt for the higher frequency AR module, whereas it is equal to 6 f rt for the lower frequency module (Figure 6c). This regime is driven by the interplay of the third-order population pulsation (PP) nonlinearity and the population grating (PG) induced in the cavity by the primary mode of the lower frequency AR, [32] the intense mode at 2.73 THz in Figure 6c.…”

Section: Resultsmentioning

confidence: 99%

Chip‐Scale Terahertz Frequency Combs through Integrated Intersubband Polariton Bleaching

Mezzapesa

Viti

et al. 2021

Laser & Photonics Reviews

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Quantum cascade lasers (QCLs) represent a fascinating accomplishment of quantum engineering and enable the direct generation of terahertz (THz) frequency radiation from an electrically biased semiconductor heterostructure. Their large spectral bandwidth, high output powers, and quantum‐limited linewidths have facilitated the realization of THz pulses by active mode‐locking and passive generation of optical frequency combs (FCs) through intracavity four‐wave‐mixing, albeit over a restricted operational regime. Here, an integrated architecture is conceived for the generation of high power (5.5–8.0 mW) THz FCs comprising an ultrafast THz polaritonic reflector, exploiting intersubband (ISB) cavity polaritons, and a broad bandwidth (2.3–3.8 THz) heterogenous THz QCL. By tuning the group‐delay‐dispersion in an integrated geometry, through the exploitation of light‐induced bleaching of the ISB‐based THz polaritons, spectral reshaping of the QCL emission and stable FC operation over an operational range up to 38%, characterized by a single and narrow (down to 700 Hz) intermode beatnote are demonstrated. This concept provides design guidelines for a new generation of compact, cost‐effective, electrically driven chip‐scale FC sources based on ultrafast polariton dynamics, paving the way toward the generation of mode‐locked THz microlasers that can strongly impact a broad range of applications in ultrafast sciences, data storage, high‐speed communication, and spectroscopy.

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Section: Resultsmentioning

confidence: 99%

Chip‐Scale Terahertz Frequency Combs through Integrated Intersubband Polariton Bleaching

Mezzapesa

Viti

et al. 2021

Laser & Photonics Reviews

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“…The efficiency of QCL 1 , defined here as the ratio between the integrated mmWave and the THz spectrum, was found to be ~1.7 × 10 −4 . Previously work has indicated the possibility of phase matching in measurements of the microwave transmission 48 and pulse generation in THz QCLs 43 , 49 . Here, using the time resolved nature of our experimental technique, we show directly the process is phase matched between the THz QCL emission and the nonlinear mmWave generation.…”

Section: Discussionmentioning

confidence: 99%

Millimeter wave photonics with terahertz semiconductor lasers

et al. 2021

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Millimeter wave (mmWave) generation using photonic techniques has so far been limited to the use of near-infrared lasers that are down-converted to the mmWave region. However, such methodologies do not currently benefit from a monolithic architecture and suffer from the quantum defect i.e. the difference in photon energies between the near-infrared and mmWave region, which can ultimately limit the conversion efficiency. Miniaturized terahertz (THz) quantum cascade lasers (QCLs) have inherent advantages in this respect: their low energy photons, ultrafast gain relaxation and high nonlinearities open up the possibility of innovatively integrating both laser action and mmWave generation in a single device. Here, we demonstrate intracavity mmWave generation within THz QCLs over the unprecedented range of 25 GHz to 500 GHz. Through ultrafast time resolved techniques, we highlight the importance of modal phases and that the process is a result of a giant second-order nonlinearity combined with a phase matched process between the THz and mmWave emission. Importantly, this work opens up the possibility of compact, low noise mmWave generation using modelocked THz frequency combs.

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“…A first striking feature is that while WF-R4 shows one pulse per roundtrip, i.e. a repetition rate of 2.43GHz, corresponding to the cavity FSR, WF-R21 shows two pulses per roundtrip, with a repetition rate at ~4.83GHz, at twice the FRS [21,36]. Red and blue dots in Fig.…”

Section: Intracavity Real-time Self-detectionmentioning

confidence: 97%

Observation of Self Mode-Locking in Terahertz Quantum Cascade Lasers through Intra-Cavity Self-Detection

Wan

et al. 2019

2019 Conference on Lasers and Electro-Optics Europe &Amp; European Quantum Electronics Conference (CLEO/Europe-EQEC)

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Mode-locking operation and multimode instabilities in Terahertz (THz) quantum cascade lasers (QCLs) have been intensively investigated during the last decade. These studies have unveiled a rich phenomenology, owing to the unique properties of these lasers, in particular their ultrafast gain medium.Thanks to this, in QCLs a modulation of the intracavity field intensity gives rise to a strong modulation of the population inversion, directly affecting the laser current. In this work we show that this property can be used to monitor in real-time the temporal dynamics of multimode THz QCLs, using a self-detection technique combined with a broadband real-time oscilloscope. We study a 4.2THz QCL operating in freerunning, and observe the formation of current pulses associated with trains of self-mode-locked optical pulses. Depending on the current pumping we find alternating regimes of unstable and stable pulse trains, respectively at the fundamental cavity repetition rate and its second harmonic. We interpret these measurements using a set of effective semiconductor Maxwell-Bloch equations that qualitatively reproduce the fundamental features of the laser dynamics, and also provide evidence in support of the solitonic nature of the observed pulses.

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Ultrafast response of harmonic modelocked THz lasers

Cited by 52 publications

References 34 publications

Chip‐Scale Terahertz Frequency Combs through Integrated Intersubband Polariton Bleaching

Chip‐Scale Terahertz Frequency Combs through Integrated Intersubband Polariton Bleaching

Millimeter wave photonics with terahertz semiconductor lasers

Observation of Self Mode-Locking in Terahertz Quantum Cascade Lasers through Intra-Cavity Self-Detection

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