Abstract
Quantum cascade lasers are, by far, the most compact, powerful, and spectrally pure sources of radiation at terahertz frequencies, and, as such, they are of crucial importance for applications in metrology, spectroscopy, imaging, and astronomy, among many others. However, for many of those applications, particularly imaging, tomography, and near-field microscopy, undesired artifacts, resulting from the use of a coherent radiation source, can be detrimental. Random lasers can offer a concrete technological solution to the above issue. They, indeed, maintain a high degree of temporal coherence, as traditional lasers, while only exhibiting low spatial coherence, which can allow for the prevention of coherent artifacts, such as speckles. In this study, we report on the development of one-dimensional THz-frequency random wire lasers, patterned on the top surface of a double-metal quantum cascade laser with fully randomly arranged apertures, not arising from the perturbation of a regular photonic structure. By performing finite element method simulations, we engineer photonic patterns supporting strongly localized random modes in the 3.05–3.5 THz range. Multimode laser emission over a tunable-by-design band of about 400 GHz and with ∼2 mW of peak power has been achieved, associated with 10° divergent optical beam patterns. The achieved performances were then compared with those of perturbed Fabry–Perot disordered lasers, showing continuous-wave operation in the 3.5–3.8 THz range with an order of magnitude larger average power output than their random counterpart, and an irregular far field emission profile.
Highlights
The terahertz (THz) region of the electromagnetic spectrum, commonly defined as the frequency range from 100 GHz to 10 THz, is of great technological and applicative interest because it connects the domains of optics and electronics, thereby offering a plethora of opportunities for developing devices, components, and systems with schemes and functionalities at the intersection between the two different domains
They, combine compactness, a broad (>1 THz) emission spectrum, resulting from ultra-broad gain bandwidths engineered by design, stable continuous-wave (CW) operation, high (1–2 W) output powers,5 intrinsically high spectral purity (100 Hz intrinsic linewidths),6 and the possibility to operate as stable optical frequency comb synthesizers
Periodic patterning has been successfully exploited in combination with miniaturized THz quantum cascade lasers (QCLs) to tailor the emission frequency,8 the optical power,9 the beam divergence and direction10 in both photonic crystals,8 distributed feedback (DFB) lasers,11–13 and resonators having different degrees of disorder, such as aperiodic one-dimensional (1D) and bi-dimensional (2D) lattices,14,15 quasi-crystals,16 and random lasers
Summary
The terahertz (THz) region of the electromagnetic spectrum, commonly defined as the frequency range from 100 GHz to 10 THz, is of great technological and applicative interest because it connects the domains of optics and electronics, thereby offering a plethora of opportunities for developing devices, components, and systems with schemes and functionalities at the intersection between the two different domains. Periodic patterning has been successfully exploited in combination with miniaturized THz QCLs to tailor the emission frequency,8 the optical power,9 the beam divergence and direction10 in both photonic crystals,8 distributed feedback (DFB) lasers,11–13 and resonators having different degrees of disorder, such as aperiodic one-dimensional (1D) and bi-dimensional (2D) lattices,14,15 quasi-crystals,16 and random lasers.17–20
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