Determination of the temperature and thermal resistance of a half-disk laser diode by measuring pulsed current-voltage characteristics
Zubov F.I. 1, Shernyakov Yu.M.2, Beckman A.A.2, Moiseev E.I.1, Salii (Guseva) Yu.A.2,1, Kulagina M.M.2, Kalyuzhnyy N.A.2, Mintairov S.А.2, Nikolaev A.V.2, Sherstnev E.V.2, Maximov M.V.1
1Alferov Federal State Budgetary Institution of Higher Education and Science Saint Petersburg National Research Academic University of the Russian Academy of Sciences, St. Petersburg, Russia
2Ioffe Institute, St. Petersburg, Russia
Email: fedyazu@mail.ru, yuri.shernyakov@mail.ioffe.ru, Arts@mail.ioffe.ru, moiseev@spbau.com, Guseva.Julia@mail.ioffe.ru, Marina.Kulagina@mail.ioffe.ru, Nickk@mail.ioffe.ru, Mintairov@scell.ioffe.ru, a.v.nikolaev@mail.ioffe.ru, 89045512456@ya.ru, maximov.mikh@gmail.com

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A technique is proposed for determining the temperature of a laser diode operating in a continuous mode, as well as thermal resistance of the device by comparing its current-voltage characteristic with pulsed current-voltage characteristics measured at different temperatures. The technique was applied to a 200 μm half-disk microlaser with an active region based on InGaAs/GaAs quantum dots. It was found that at currents corresponding to the peak laser power and lasing quenching due to overheating of the active region, the device temperature reaches 101 and 149oC, respectively. The thermal resistance of the laser is 110 K/W. Keywords: half-disk microlaser, laser temperature, thermal resistance, quantum dots, laser diodes.
  1. T.W. Hansch, G.T. Kamiya, T.F. Krausz, G.B. Monemar, L.M. Ohtsu, T.H. Venghaus, B.H. Weber, B.H. Weinfurter. High Power Diode Lasers (Springer New York, N. Y., 2007)
  2. A.S. Payusov, A.A. Beckman, G.O. Kornyshov, Yu.M. Shernyakov, M.V. Maximov, N.Yu. Gordeev. Semiconductors, 56, 919 (2022). http://dx.doi.org/10.21883/SC.2022.12.55152.4409
  3. F. Zubov, M. Maximov, E. Moiseev, A. Vorobyev, A. Mozharov, Yu. Berdnikov, N. Kalyuzhnyy, S. Mintairov, M. Kulagina, N. Kryzhanovskaya, A. Zhukov. Optics Lett., 46, 3853 (2021). https://doi.org/10.1364/OL.432920
  4. Patent US8112243
  5. S.S. Saini, S.H. Cho, M. Dagenais. Photonics Packag. Integr. Interconnects VII, 6478, 647805 (2007). https://doi.org/10.1117/12.714295
  6. M.V. Maximov, A.M. Nadtochiy, S.A. Mintairov, N.A. Kalyuzhnyy, N.V. Kryzhanovskaya, E.I. Moiseev, N.Y. Gordeev, Y.M. Shernyakov, A.S. Payusov, F.I. Zubov, V.N. Nevedomskiy, S.S. Rouvimov, A.E. Zhukov. Appl. Sci., 10, 1038 (2020). https://doi.org/10.3390/app10031038
  7. F.I. Zubov, E.I. Moiseev, M.V. Maximov, A.A. Vorobyev, A.M. Mozharov, N.A. Kaluzhnyy, S.A. Mintairov, M.M. Kulagina, N.V. Kryzhanovskaya, A.E. Zhukov. IEEE Photon. Technol. Lett., 34, 1349 (2020). https://doi.org/10.1109/LPT.2022.3216738
  8. F.I. Zubov, E.I. Moiseev, M.V. Maximov, A.A. Vorobyev, A.M. Mozharov, Yu.M. Shernyakov, N.A. Kalyuzhnyy, S.A. Mintairov, M.M. Kulagina, V.G. Dubrovskii, N.V. Kryzhanovskaya, A.E. Zhukov. Laser Phys., 32, 125802 (2022). https://doi.org/10.1088/1555-6611/ac996f
  9. F. Zubov, E. Moiseev, M. Maximov, A. Vorobyev, A. Mozharov, Y. Shernyakov, N. Kalyuzhnyy, S. Mintairov, M. Kulagina, V. Dubrovskii, N. Kryzhanovskaya, A. Zhukov. Photonics, 10, 290 (2023). https://doi.org/10.3390/photonics10030290

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