Diagnostics of the dynamics of material damage by thermal shocks with the intensity possible in the ITER divertor

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Diagnostics of the dynamics of material damage by thermal shocks with the intensity possible in the ITER divertor. / Vyacheslavov, L. N.; Arakcheev, A. S.; Bataev, I. A. et al.

In: Physica Scripta, Vol. 93, No. 3, 035602, 03.2018.

Research output: Contribution to journal › Article › peer-review

Harvard

Vyacheslavov, LN, Arakcheev, AS, Bataev, IA, Burdakov, AV, Kandaurov, IV, Kasatov, AA, Kurkuchekov, VV, Popov, VA, Shoshin, AA , Skovorodin, DI, Trunev, YA & Vasilyev, AA 2018, 'Diagnostics of the dynamics of material damage by thermal shocks with the intensity possible in the ITER divertor', Physica Scripta, vol. 93, no. 3, 035602. https://doi.org/10.1088/1402-4896/aaa119

APA

Vyacheslavov, L. N., Arakcheev, A. S., Bataev, I. A., Burdakov, A. V., Kandaurov, I. V., Kasatov, A. A., Kurkuchekov, V. V., Popov, V. A., Shoshin, A. A., Skovorodin, D. I., Trunev, Y. A., & Vasilyev, A. A. (2018). Diagnostics of the dynamics of material damage by thermal shocks with the intensity possible in the ITER divertor. Physica Scripta, 93(3), [035602]. https://doi.org/10.1088/1402-4896/aaa119

Vancouver

Vyacheslavov LN, Arakcheev AS, Bataev IA, Burdakov AV, Kandaurov IV, Kasatov AA et al. Diagnostics of the dynamics of material damage by thermal shocks with the intensity possible in the ITER divertor. Physica Scripta. 2018 Mar;93(3):035602. doi: 10.1088/1402-4896/aaa119

Author

Vyacheslavov, L. N. ; Arakcheev, A. S. ; Bataev, I. A. et al. / Diagnostics of the dynamics of material damage by thermal shocks with the intensity possible in the ITER divertor. In: Physica Scripta. 2018 ; Vol. 93, No. 3.

BibTeX

@article{bbe12c302851451a9edb54e3b030f36b,

title = "Diagnostics of the dynamics of material damage by thermal shocks with the intensity possible in the ITER divertor",

abstract = "A novel BETA test facility (Beam of Electrons for materials Test Applications) was developed at the Budker Institute to study the erosion of materials directly during the impact of intense thermal shocks. A powerful (up to 7 MW) long pulse (100-300 μs) electron beam is applied for experimental simulation of fast transient heat loads with the intensity probable in the ITER divertor. The heat flux parameter on a target can be widely varied (FHF = 10-300 MW m-2 s0.5) from a value significantly below the melting threshold to a value much higher, within the area of about 1 cm2. The use of an electron beam to simulate the thermal impact on the material surface makes it possible to employ a variety of optical diagnostics for in situ observations of the dynamics of surface erosion processes during intense thermal shocks. These distinctive features make BETA a promising tool in the research of material surface erosion mechanisms and for experimental verification of various analytical and numerical models associated with these mechanisms. The first results obtained with this facility include fast (10 μs exposure) imaging of the heated target in the near-infrared range and in the reflected light of 532 nm continuous wave (CW) laser, visualization of ejected tungsten particles using fast ICCD and CCD cameras with the minimal exposure of 2 μs and 7 μs respectively. The dynamics of dust particles ejected from the heated surface is investigated using a multichannel recording of the light of 532 nm CW-laser scattered on the dust particles. The present paper describes the first results of use of two new in situ methods: continuous recording of light scattered from the tungsten surface and three-dimensional tracking of tungsten particles using three viewing angles. The first method makes it possible to observe the dynamics of development of roughness and cracking of the polished tungsten surface, which manifest themselves as two successive processes separated by a large time delay. The second method allows us to track dust particles ejected from the melt layer, and thus determine the time and place of particle ejection from the surface.",

keywords = "experimental simulation, high-power submillisecond electron beam, in situ optical diagnostics, ITER-scale fast transient heat loads, DUST, SURFACE, TUNGSTEN, SIMULATION, HEAT LOADS",

author = "Vyacheslavov, {L. N.} and Arakcheev, {A. S.} and Bataev, {I. A.} and Burdakov, {A. V.} and Kandaurov, {I. V.} and Kasatov, {A. A.} and Kurkuchekov, {V. V.} and Popov, {V. A.} and Shoshin, {A. A.} and Skovorodin, {D. I.} and Trunev, {Yu A.} and Vasilyev, {A. A.}",

note = "Publisher Copyright: {\textcopyright} 2018 IOP Publishing Ltd.",

year = "2018",

month = mar,

doi = "10.1088/1402-4896/aaa119",

language = "English",

volume = "93",

journal = "Physica Scripta",

issn = "0031-8949",

publisher = "IOP Publishing Ltd.",

number = "3",

}

RIS

TY - JOUR

T1 - Diagnostics of the dynamics of material damage by thermal shocks with the intensity possible in the ITER divertor

AU - Vyacheslavov, L. N.

AU - Arakcheev, A. S.

AU - Bataev, I. A.

AU - Burdakov, A. V.

AU - Kandaurov, I. V.

AU - Kasatov, A. A.

AU - Kurkuchekov, V. V.

AU - Popov, V. A.

AU - Shoshin, A. A.

AU - Skovorodin, D. I.

AU - Trunev, Yu A.

AU - Vasilyev, A. A.

PY - 2018/3

Y1 - 2018/3

N2 - A novel BETA test facility (Beam of Electrons for materials Test Applications) was developed at the Budker Institute to study the erosion of materials directly during the impact of intense thermal shocks. A powerful (up to 7 MW) long pulse (100-300 μs) electron beam is applied for experimental simulation of fast transient heat loads with the intensity probable in the ITER divertor. The heat flux parameter on a target can be widely varied (FHF = 10-300 MW m-2 s0.5) from a value significantly below the melting threshold to a value much higher, within the area of about 1 cm2. The use of an electron beam to simulate the thermal impact on the material surface makes it possible to employ a variety of optical diagnostics for in situ observations of the dynamics of surface erosion processes during intense thermal shocks. These distinctive features make BETA a promising tool in the research of material surface erosion mechanisms and for experimental verification of various analytical and numerical models associated with these mechanisms. The first results obtained with this facility include fast (10 μs exposure) imaging of the heated target in the near-infrared range and in the reflected light of 532 nm continuous wave (CW) laser, visualization of ejected tungsten particles using fast ICCD and CCD cameras with the minimal exposure of 2 μs and 7 μs respectively. The dynamics of dust particles ejected from the heated surface is investigated using a multichannel recording of the light of 532 nm CW-laser scattered on the dust particles. The present paper describes the first results of use of two new in situ methods: continuous recording of light scattered from the tungsten surface and three-dimensional tracking of tungsten particles using three viewing angles. The first method makes it possible to observe the dynamics of development of roughness and cracking of the polished tungsten surface, which manifest themselves as two successive processes separated by a large time delay. The second method allows us to track dust particles ejected from the melt layer, and thus determine the time and place of particle ejection from the surface.

AB - A novel BETA test facility (Beam of Electrons for materials Test Applications) was developed at the Budker Institute to study the erosion of materials directly during the impact of intense thermal shocks. A powerful (up to 7 MW) long pulse (100-300 μs) electron beam is applied for experimental simulation of fast transient heat loads with the intensity probable in the ITER divertor. The heat flux parameter on a target can be widely varied (FHF = 10-300 MW m-2 s0.5) from a value significantly below the melting threshold to a value much higher, within the area of about 1 cm2. The use of an electron beam to simulate the thermal impact on the material surface makes it possible to employ a variety of optical diagnostics for in situ observations of the dynamics of surface erosion processes during intense thermal shocks. These distinctive features make BETA a promising tool in the research of material surface erosion mechanisms and for experimental verification of various analytical and numerical models associated with these mechanisms. The first results obtained with this facility include fast (10 μs exposure) imaging of the heated target in the near-infrared range and in the reflected light of 532 nm continuous wave (CW) laser, visualization of ejected tungsten particles using fast ICCD and CCD cameras with the minimal exposure of 2 μs and 7 μs respectively. The dynamics of dust particles ejected from the heated surface is investigated using a multichannel recording of the light of 532 nm CW-laser scattered on the dust particles. The present paper describes the first results of use of two new in situ methods: continuous recording of light scattered from the tungsten surface and three-dimensional tracking of tungsten particles using three viewing angles. The first method makes it possible to observe the dynamics of development of roughness and cracking of the polished tungsten surface, which manifest themselves as two successive processes separated by a large time delay. The second method allows us to track dust particles ejected from the melt layer, and thus determine the time and place of particle ejection from the surface.

KW - experimental simulation

KW - high-power submillisecond electron beam

KW - in situ optical diagnostics

KW - ITER-scale fast transient heat loads

KW - DUST

KW - SURFACE

KW - TUNGSTEN

KW - SIMULATION

KW - HEAT LOADS

UR - http://www.scopus.com/inward/record.url?scp=85043525106&partnerID=8YFLogxK

U2 - 10.1088/1402-4896/aaa119

DO - 10.1088/1402-4896/aaa119

M3 - Article

AN - SCOPUS:85043525106

VL - 93

JO - Physica Scripta

JF - Physica Scripta

SN - 0031-8949

IS - 3

M1 - 035602

ER -

ID: 10415370