Review of Works on Plasma-Surface Interaction at the Budker Institute

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Review of Works on Plasma-Surface Interaction at the Budker Institute. / Shoshin, A. A.; Burdakov, A. V.; Kandaurov, I. V. et al.

In: Physics of Atomic Nuclei, Vol. 87, No. Suppl 1, 23.01.2025, p. S70-S79.

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

Harvard

Shoshin, AA, Burdakov, AV, Kandaurov, IV, Kasatov, AA, Kazantsev, SR, Balash, II, Popov, VA, Ryzhkov, GA, Cherepanov, DE, Kuzmin, EI, Polosatkin, SV , Ivanov, IA, Arakcheev, AS & Vasilyev, AA 2025, 'Review of Works on Plasma-Surface Interaction at the Budker Institute', Physics of Atomic Nuclei, vol. 87, no. Suppl 1, pp. S70-S79. https://doi.org/10.1134/S1063778824130118

APA

Shoshin, A. A., Burdakov, A. V., Kandaurov, I. V., Kasatov, A. A., Kazantsev, S. R., Balash, I. I., Popov, V. A., Ryzhkov, G. A., Cherepanov, D. E., Kuzmin, E. I., Polosatkin, S. V., Ivanov, I. A., Arakcheev, A. S., & Vasilyev, A. A. (2025). Review of Works on Plasma-Surface Interaction at the Budker Institute. Physics of Atomic Nuclei, 87(Suppl 1), S70-S79. https://doi.org/10.1134/S1063778824130118

Vancouver

Shoshin AA, Burdakov AV, Kandaurov IV, Kasatov AA, Kazantsev SR, Balash II et al. Review of Works on Plasma-Surface Interaction at the Budker Institute. Physics of Atomic Nuclei. 2025 Jan 23;87(Suppl 1):S70-S79. doi: 10.1134/S1063778824130118

Author

Shoshin, A. A. ; Burdakov, A. V. ; Kandaurov, I. V. et al. / Review of Works on Plasma-Surface Interaction at the Budker Institute. In: Physics of Atomic Nuclei. 2025 ; Vol. 87, No. Suppl 1. pp. S70-S79.

BibTeX

@article{9f65c359ee944fe0b93ae6fd52f78c0d,

title = "Review of Works on Plasma-Surface Interaction at the Budker Institute",

abstract = "Since the 1990s, comprehensive studies of the interaction of powerful plasma streams, electron beams, and laser radiation with solid bodies have been carried out at the Budker Institute of Nuclear Physics under loads expected at the first wall of a fusion reactor. First, the experiments have been performed using the GOL-3 facility, then the BETA bench. At the moment, new experimental facilities are being set up, including the Plasma Station at the under-construction SKIF synchrotron radiation source, and a new-generation open-trap GDMT reactor is being designed. The properties of near-surface plasma and its dynamics (density, temperature, velocity, charge composition) have been investigated using the developed diagnostic complex of the GOL-3 multimirror trap. Surface modification of various materials (tungsten, graphite, ceramics) under different pulse thermal loads has been studied. The use of the electron beam on BETA bench allowed in situ observation of surface modification processes during thermal shock, which is unavailable for plasma impact facilities. Comparison with the data of other researchers has been performed and their consistency with each other has been shown. Thresholds for cracking and melting of tungsten, explosive (brittle) fracture of graphite have been obtained. Synchrotron radiation has been used to study stresses in materials, with which stresses during pulsed irradiation have been measured with high temporal resolution. Experimental work is supplemented by theoretical and computational studies. A model of tungsten fracture is proposed according to which stresses leading to tungsten cracking occur at the cooling stage. For the first time in the world, the appearance of cracks significantly later than the thermal load has been experimentally observed using the BETA bench.",

keywords = "ceramics, first wall, fusion reactor, graphite, powerful energy flows, pulsed heating, synchrotron radiation, thermal shocks, tungsten",

author = "Shoshin, {A. A.} and Burdakov, {A. V.} and Kandaurov, {I. V.} and Kasatov, {A. A.} and Kazantsev, {S. R.} and Balash, {I. I.} and Popov, {V. A.} and Ryzhkov, {G. A.} and Cherepanov, {D. E.} and Kuzmin, {E. I.} and Polosatkin, {S. V.} and Ivanov, {I. A.} and Arakcheev, {A. S.} and Vasilyev, {A. A.}",

note = "The work on adapting laser heating system for testing ceramics was supported in part by the Russian Science Foundation (project no. 23-19-00212).",

year = "2025",

month = jan,

day = "23",

doi = "10.1134/S1063778824130118",

language = "English",

volume = "87",

pages = "S70--S79",

journal = "Physics of Atomic Nuclei",

issn = "1063-7788",

publisher = "Maik Nauka-Interperiodica Publishing",

number = "Suppl 1",

}

RIS

TY - JOUR

T1 - Review of Works on Plasma-Surface Interaction at the Budker Institute

AU - Shoshin, A. A.

AU - Burdakov, A. V.

AU - Kandaurov, I. V.

AU - Kasatov, A. A.

AU - Kazantsev, S. R.

AU - Balash, I. I.

AU - Popov, V. A.

AU - Ryzhkov, G. A.

AU - Cherepanov, D. E.

AU - Kuzmin, E. I.

AU - Polosatkin, S. V.

AU - Ivanov, I. A.

AU - Arakcheev, A. S.

AU - Vasilyev, A. A.

N1 - The work on adapting laser heating system for testing ceramics was supported in part by the Russian Science Foundation (project no. 23-19-00212).

PY - 2025/1/23

Y1 - 2025/1/23

N2 - Since the 1990s, comprehensive studies of the interaction of powerful plasma streams, electron beams, and laser radiation with solid bodies have been carried out at the Budker Institute of Nuclear Physics under loads expected at the first wall of a fusion reactor. First, the experiments have been performed using the GOL-3 facility, then the BETA bench. At the moment, new experimental facilities are being set up, including the Plasma Station at the under-construction SKIF synchrotron radiation source, and a new-generation open-trap GDMT reactor is being designed. The properties of near-surface plasma and its dynamics (density, temperature, velocity, charge composition) have been investigated using the developed diagnostic complex of the GOL-3 multimirror trap. Surface modification of various materials (tungsten, graphite, ceramics) under different pulse thermal loads has been studied. The use of the electron beam on BETA bench allowed in situ observation of surface modification processes during thermal shock, which is unavailable for plasma impact facilities. Comparison with the data of other researchers has been performed and their consistency with each other has been shown. Thresholds for cracking and melting of tungsten, explosive (brittle) fracture of graphite have been obtained. Synchrotron radiation has been used to study stresses in materials, with which stresses during pulsed irradiation have been measured with high temporal resolution. Experimental work is supplemented by theoretical and computational studies. A model of tungsten fracture is proposed according to which stresses leading to tungsten cracking occur at the cooling stage. For the first time in the world, the appearance of cracks significantly later than the thermal load has been experimentally observed using the BETA bench.

AB - Since the 1990s, comprehensive studies of the interaction of powerful plasma streams, electron beams, and laser radiation with solid bodies have been carried out at the Budker Institute of Nuclear Physics under loads expected at the first wall of a fusion reactor. First, the experiments have been performed using the GOL-3 facility, then the BETA bench. At the moment, new experimental facilities are being set up, including the Plasma Station at the under-construction SKIF synchrotron radiation source, and a new-generation open-trap GDMT reactor is being designed. The properties of near-surface plasma and its dynamics (density, temperature, velocity, charge composition) have been investigated using the developed diagnostic complex of the GOL-3 multimirror trap. Surface modification of various materials (tungsten, graphite, ceramics) under different pulse thermal loads has been studied. The use of the electron beam on BETA bench allowed in situ observation of surface modification processes during thermal shock, which is unavailable for plasma impact facilities. Comparison with the data of other researchers has been performed and their consistency with each other has been shown. Thresholds for cracking and melting of tungsten, explosive (brittle) fracture of graphite have been obtained. Synchrotron radiation has been used to study stresses in materials, with which stresses during pulsed irradiation have been measured with high temporal resolution. Experimental work is supplemented by theoretical and computational studies. A model of tungsten fracture is proposed according to which stresses leading to tungsten cracking occur at the cooling stage. For the first time in the world, the appearance of cracks significantly later than the thermal load has been experimentally observed using the BETA bench.

KW - ceramics

KW - first wall

KW - fusion reactor

KW - graphite

KW - powerful energy flows

KW - pulsed heating

KW - synchrotron radiation

KW - thermal shocks

KW - tungsten

UR - https://www.mendeley.com/catalogue/f7345e99-c3c0-3c2f-a96a-d46f4076ecdd/

U2 - 10.1134/S1063778824130118

DO - 10.1134/S1063778824130118

M3 - Article

VL - 87

SP - S70-S79

JO - Physics of Atomic Nuclei

JF - Physics of Atomic Nuclei

SN - 1063-7788

IS - Suppl 1

ER -

ID: 64832920