TY - JOUR

T1 - Pyrometry accuracy of a tungsten surface heated by sub-millisecond laser radiation

AU - Ryzhkov, G. A.

AU - Vyacheslavov, L. N.

AU - Kasatov, A. A.

AU - Popov, V. A.

AU - Cherepanov, D. E.

N1 - Ryzhkov G.A., Vyacheslavov L.N., Kasatov A.A., Popov V.A., Cherepanov D.E. Pyrometry accuracy of a tungsten surface heated by sub-millisecond laser radiation

PY - 2025

Y1 - 2025

N2 - An experimental facility has been created at the BINP SB RAS for simulating pulsed thermal loads using a laser pulse of submillisecond duration. Tungsten was used as the test sample material, for which the surface temperature was determined by pyrometry. The main factors affecting the temperature measurement accuracy by this method are that there is a need to take into account the surface roughness of the samples and the literature contains different emissivity data, which are not consistent with each other. However, the results of theoretical simulation showed these factors have little effect on pyrometry accuracy. Based on the thermophysical data of tungsten and the parameters of the laser pulse, the temporal dynamics of the tungsten surface temperature during thermal shock was simulated. The obtained experimental data are consistent with theoretical simulation.

AB - An experimental facility has been created at the BINP SB RAS for simulating pulsed thermal loads using a laser pulse of submillisecond duration. Tungsten was used as the test sample material, for which the surface temperature was determined by pyrometry. The main factors affecting the temperature measurement accuracy by this method are that there is a need to take into account the surface roughness of the samples and the literature contains different emissivity data, which are not consistent with each other. However, the results of theoretical simulation showed these factors have little effect on pyrometry accuracy. Based on the thermophysical data of tungsten and the parameters of the laser pulse, the temporal dynamics of the tungsten surface temperature during thermal shock was simulated. The obtained experimental data are consistent with theoretical simulation.

KW - laser heating

KW - plasma-facing components

KW - plasma-surface interaction

KW - pyrometry

KW - spectral emissivity

KW - surface roughness

KW - thermal shock

KW - tungsten

KW - ВЗАИМОДЕЙСТВИЕ ПЛАЗМЫ С ПОВЕРХНОСТЬЮ

KW - ОБРАЩЁННЫЕ К ПЛАЗМЕ КОМПОНЕНТЫ

KW - ВОЛЬФРАМ

KW - ЛАЗЕРНЫЙ НАГРЕВ

KW - ТЕРМОУДАР

KW - ПИРОМЕТРИЯ

KW - СПЕКТРАЛЬНАЯ ИЗЛУЧАТЕЛЬНАЯ СПОСОБНОСТЬ

KW - ШЕРОХОВАТОСТЬ ПОВЕРХНОСТИ

UR - https://www.scopus.com/pages/publications/105020707747

UR - https://www.elibrary.ru/item.asp?id=82831209

UR - https://www.mendeley.com/catalogue/60e38f38-79a4-3f37-8eb5-b3f65fc9ecc4/

M3 - Article

VL - 48

SP - 137

EP - 151

JO - Problems of Atomic Science and Technology, Series Thermonuclear Fusion

JF - Problems of Atomic Science and Technology, Series Thermonuclear Fusion

SN - 0202-3822

IS - 1

M1 - 15

ER -