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Remote measurement of the temperature distribution on the surface of solids under high-power laser irradiation

, , , ,
Scientific and Technological Center of Unique Instrumentation of the Russian Academy of Sciences, ul. Butlerova 15, Moscow, 117342, Russian Federation

The paper reviews the latest results on the application of hyperspectral imaging to measure the temperature distribution and the emissivity on the surface of solids under laser heating in diamond anvil cells. In 2016, it was proposed to use a double acousto-optic filter, which enabled obtaining a large set of experimental points on the Planck curve and achieving a high accuracy of temperature determination. Employing an acousto-optic filter also makes it possible to visualize the intensity distribution of infrared laser radiation, study melting, and meas„ure the thermal conductivity of metals at high pressures and temperatures.

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Fulltext is also available at DOI: 10.3367/UFNe.2021.05.038996
Keywords: laser heating, temperature distribution, high pressures, emissivity, thermal radiation, phase transitions, diamond anvil cells
PACS: 07.35.+k, 07.60.−j, 42.79.Jq (all)
DOI: 10.3367/UFNe.2021.05.038996
URL: https://ufn.ru/en/articles/2022/8/e/
001099034300005
2-s2.0-85182914505
Citation: Zinin P V, Bulatov K M, Bykov A A, Mantrova Yu V, Kutuza I B "Remote measurement of the temperature distribution on the surface of solids under high-power laser irradiation" Phys. Usp. 65 852–863 (2022)
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Received: 1st, April 2021, revised: 18th, May 2021, 24th, May 2021

Оригинал: Зинин П В, Булатов К М, Быков А А, Мантрова Ю В, Кутуза И Б «Дистанционное измерение распределения температуры на поверхности твёрдых тел при воздействии мощного лазерного излучения» УФН 192 913–925 (2022); DOI: 10.3367/UFNr.2021.05.038996

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  1. A.S. Pirozhkov, E.N. Ragozin “Aperiodic multilayer structures in soft X-ray optics58 1095–1105 (2015)
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  3. E.N. Ragozin, E.A. Vishnyakov et alSoft X-ray spectrometers based on aperiodic reflection gratings and their application64 495–514 (2021)
  4. M.I. Lomaev, V.S. Skakun et alExcilamps: efficient sources of spontaneous UV and VUV radiation46 193–209 (2003)
  5. D.V. Kazantsev, E.A. Kazantseva “Scattering type apertureless scaning near-field optical microscopy”, accepted
  6. A.B. Medvedev, R.F. Trunin “Shock compression of porous metals and silicates55 773–789 (2012)
  7. M.A. Proskurnin, V.R. Khabibullin et alPhotothermal and optoacoustic spectroscopy: state of the art and prospects65 270–312 (2022)
  8. S.G. Rautian “Real spectral apparatus1 245–273 (1958)
  9. R.F. Trunin, V.D. Urlin, A.B. Medvedev “Dynamic compression of hydrogen isotopes at megabar pressures53 577–593 (2010)
  10. G.R. Ivanitskii “Modern matrix thermovision in biomedicine49 1263–1288 (2006)
  11. V.V. Brazhkin ““Lost in Translation”: what do the negative values of effective Grüneisen coefficients mean in shock wave experiments? [Extended comment on “Shock compression of porous metals and silicates” by A B Medvedev and R F Trunin, Phys. Usp. 55 773 (2012)]55 790–795 (2012)
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  13. V.V. Busarev, V.V. Prokof’eva-Mikhailovskaya, V.V. Bochkov “Spectral and spectral-frequency methods of investigating atmosphereless bodies of the Solar system50 637–647 (2007)
  14. I.Yu. Eremchev, D.V. Prokopova et alThree-dimensional fluorescence nanoscopy of single quantum emitters based on the optics of spiral light beams65 617–626 (2022)
  15. V.V. Lider “X-ray crystal interferometers57 1099–1117 (2014)
  16. R.A. Ganeev “Generation of high-order harmonics of high-power lasers in plasmas produced under irradiation of solid target surfaces by a prepulse52 55–77 (2009)

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