Sensors (Nov 2020)

Widely-Tunable Quantum Cascade-Based Sources for the Development of Optical Gas Sensors

  • Virginie Zéninari,
  • Raphaël Vallon,
  • Laurent Bizet,
  • Clément Jacquemin,
  • Guillaume Aoust,
  • Grégory Maisons,
  • Mathieu Carras,
  • Bertrand Parvitte

DOI
https://doi.org/10.3390/s20226650
Journal volume & issue
Vol. 20, no. 22
p. 6650

Abstract

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Spectroscopic techniques based on Distributed FeedBack (DFB) Quantum Cascade Lasers (QCL) provide good results for gas detection in the mid-infrared region in terms of sensibility and selectivity. The main limitation is the QCL relatively low tuning range (~10 cm−1) that prevents from monitoring complex species with broad absorption spectra in the infrared region or performing multi-gas sensing. To obtain a wider tuning range, the first solution presented in this paper consists of the use of a DFB QCL array. Tuning ranges from 1335 to 1387 cm−1 and from 2190 to 2220 cm−1 have been demonstrated. A more common technique that will be presented in a second part is to implement a Fabry–Perot QCL chip in an external-cavity (EC) system so that the laser could be tuned on its whole gain curve. The use of an EC system also allows to perform Intra-Cavity Laser Absorption Spectroscopy, where the gas sample is placed within the laser resonator. Moreover, a technique only using the QCL compliance voltage technique can be used to retrieve the spectrum of the gas inside the cavity, thus no detector outside the cavity is needed. Finally, a specific scheme using an EC coherent QCL array can be developed. All these widely-tunable Quantum Cascade-based sources can be used to demonstrate the development of optical gas sensors.

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