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Quantum cascade detectors for the 8 μm spectral range
Russian version
Dudelev V. V.1, Chistyakov D. V. 1, Podoprigora V. V. 1,2, Nikitin A. A.1,2, Mikhailov D. A.1, Cherotchenko E. D.1, Vrubel I. I.1, Mylnikov V. Yu.1, Losev S. N.1, Deryagin N. G.1, Abdulrazak S. H.1, Andreev A. D.1, Deryagin A. G.1, Babichev A. V.1, Lutetskiy A. V.1, Slipchenko S. O.1, Pikhtin N. A.1, Gladyshev A. G. 3, Podgaetskiy K. A.4, Andreev A. Yu.4, Yarotskaya I. V.4, Ladugin M. A.4, Marmalyuk A. A.4, Papylev D. S.5, Novikov I. I.3,5, Kognovitskaya E. A.1,6, Kuchinskii V. I.1, Karachinsky L. Ya.3,5, Egorov A. Yu.3, Sokolovskii G. S.1
1Ioffe Institute, St. Petersburg, Russia
2St. Petersburg State Electrotechnical University “LETI", St. Petersburg, Russia
3Connector Optics LLC, St. Petersburg, Russia
4“Polyus” Research Institute of M.F. Stelmakh Joint Stock Company, Moscow, Russia
5ITMO University, St. Petersburg, Russia
6D.I. Mendeleev Institute for Metrology, St. Petersburg, Russia
Email: v.dudelev@mail.ru
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Quantum cascade detectors (QCDs) operating at room temperature and zero bias with extremely low dark current are a promising platform for creating high-speed detectors in the long-wave infrared range for wireless optical communication systems. Producing QCDs from the quantum cascade laser (QCL) heterostructures opens up opportunities for integrating sources and detectors on a common wafer. We have demonstrated a maximum QCD sensitivity of over 70 mA/W in the 8 μm region and implemented the concept of integrating QCD on a single heat sink with QCL to create a feedback photodetector. Preliminary performance studies have shown that the QCD bandwidth exceeds 1 GHz and may be significantly increased by optimizing the capacitive characteristics. Keywords: quantum cascade detector, quantum cascade laser, feedback photodetector, bandwidth.
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