Application of dense plasma focus devices and lasers in the radiation material sciences for the goals of inertial fusion beyond ignition

Application of dense plasma focus devices and lasers in the radiation material sciences for the goals of inertial fusion beyond ignition

Specimens of materials for prospective use in chambers of nuclear fusion reactors with inertial plasma confinement, namely, W, ODS steels, Eurofer 97 steel, a number of ceramics, etc., have been irradiated by dense plasma focus devices and a laser in the Q-switched mode...

Full description

Bibliographic Details
Main Authors: V. A. Gribkov, I. V. Borovitskaya, E. V. Demina, E. E. Kazilin, S. V. Latyshev, S. A. Maslyaev, V. N. Pimenov, T. Laas, M. Paduch, S. V. Rogozhkin
Format: Article
Language:English
Published: AIP Publishing LLC 2020-07-01
Series:Matter and Radiation at Extremes
Online Access:http://dx.doi.org/10.1063/5.0005852
id doaj-cc09ca661de34cb08b69e8a657e7ff8c
record_format Article
spelling doaj-cc09ca661de34cb08b69e8a657e7ff8c2020-11-25T03:48:31ZengAIP Publishing LLCMatter and Radiation at Extremes2468-080X2020-07-0154045403045403-1910.1063/5.0005852Application of dense plasma focus devices and lasers in the radiation material sciences for the goals of inertial fusion beyond ignitionV. A. Gribkov0I. V. Borovitskaya1E. V. Demina2E. E. Kazilin3S. V. Latyshev4S. A. Maslyaev5V. N. Pimenov6T. Laas7M. Paduch8S. V. Rogozhkin9A.A. Baikov Institute of Metallurgy and Material Science, RAS, Leninsky Prospect 49, 119991 Moscow, Russian FederationA.A. Baikov Institute of Metallurgy and Material Science, RAS, Leninsky Prospect 49, 119991 Moscow, Russian FederationA.A. Baikov Institute of Metallurgy and Material Science, RAS, Leninsky Prospect 49, 119991 Moscow, Russian FederationA.A. Baikov Institute of Metallurgy and Material Science, RAS, Leninsky Prospect 49, 119991 Moscow, Russian FederationA.A. Baikov Institute of Metallurgy and Material Science, RAS, Leninsky Prospect 49, 119991 Moscow, Russian FederationA.A. Baikov Institute of Metallurgy and Material Science, RAS, Leninsky Prospect 49, 119991 Moscow, Russian FederationA.A. Baikov Institute of Metallurgy and Material Science, RAS, Leninsky Prospect 49, 119991 Moscow, Russian FederationThe International Centre for Dense Magnetized Plasmas, ul. Hery 23, 01-497 Warsaw, PolandThe International Centre for Dense Magnetized Plasmas, ul. Hery 23, 01-497 Warsaw, PolandA.I. Alikhanov Institute for Theoretical and Experimental Physics of NRC “Kurchatov Institute”, ul. Bolshaya Cheremushkinskaya 25, 117218 Moscow, Russian FederationSpecimens of materials for prospective use in chambers of nuclear fusion reactors with inertial plasma confinement, namely, W, ODS steels, Eurofer 97 steel, a number of ceramics, etc., have been irradiated by dense plasma focus devices and a laser in the Q-switched mode of operation with a wide range of parameters, including some that noticeably exceeded those expected in reactors. By means of 1-ns laser interferometry and neutron measurements, the characteristics of plasma streams and fast ion beams, as well as the dynamics of their interaction with solid-state targets, have been investigated. 3D profilometry, optical and scanning electron microscopy, atomic emission spectroscopy, X-ray elemental and structural analyses, and precise weighing of specimens before and after irradiation have provided data on the roughening threshold and the susceptibility to damage of the materials under investigation. Analysis of the results, together with numerical modeling, has revealed the important role of shock waves in the damage processes. It has been shown that a so-called integral damage factor may be used only within restricted ranges of the irradiation parameters. It has also been found that in the irradiation regime with well-developed gasdynamic motion of secondary plasma, the overall amount of radiation energy is spent preferentially either on removing large masses of cool matter from the material surface or on heating a small amount of plasma to high temperature (and, consequently, imparting to it a high velocity), depending on the power flux density and characteristics of the pulsed irradiation.http://dx.doi.org/10.1063/5.0005852
collection DOAJ
language English
format Article
sources DOAJ
author V. A. Gribkov
I. V. Borovitskaya
E. V. Demina
E. E. Kazilin
S. V. Latyshev
S. A. Maslyaev
V. N. Pimenov
T. Laas
M. Paduch
S. V. Rogozhkin
spellingShingle V. A. Gribkov
I. V. Borovitskaya
E. V. Demina
E. E. Kazilin
S. V. Latyshev
S. A. Maslyaev
V. N. Pimenov
T. Laas
M. Paduch
S. V. Rogozhkin
Application of dense plasma focus devices and lasers in the radiation material sciences for the goals of inertial fusion beyond ignition
Matter and Radiation at Extremes
author_facet V. A. Gribkov
I. V. Borovitskaya
E. V. Demina
E. E. Kazilin
S. V. Latyshev
S. A. Maslyaev
V. N. Pimenov
T. Laas
M. Paduch
S. V. Rogozhkin
author_sort V. A. Gribkov
title Application of dense plasma focus devices and lasers in the radiation material sciences for the goals of inertial fusion beyond ignition
title_short Application of dense plasma focus devices and lasers in the radiation material sciences for the goals of inertial fusion beyond ignition
title_full Application of dense plasma focus devices and lasers in the radiation material sciences for the goals of inertial fusion beyond ignition
title_fullStr Application of dense plasma focus devices and lasers in the radiation material sciences for the goals of inertial fusion beyond ignition
title_full_unstemmed Application of dense plasma focus devices and lasers in the radiation material sciences for the goals of inertial fusion beyond ignition
title_sort application of dense plasma focus devices and lasers in the radiation material sciences for the goals of inertial fusion beyond ignition
publisher AIP Publishing LLC
series Matter and Radiation at Extremes
issn 2468-080X
publishDate 2020-07-01
description Specimens of materials for prospective use in chambers of nuclear fusion reactors with inertial plasma confinement, namely, W, ODS steels, Eurofer 97 steel, a number of ceramics, etc., have been irradiated by dense plasma focus devices and a laser in the Q-switched mode of operation with a wide range of parameters, including some that noticeably exceeded those expected in reactors. By means of 1-ns laser interferometry and neutron measurements, the characteristics of plasma streams and fast ion beams, as well as the dynamics of their interaction with solid-state targets, have been investigated. 3D profilometry, optical and scanning electron microscopy, atomic emission spectroscopy, X-ray elemental and structural analyses, and precise weighing of specimens before and after irradiation have provided data on the roughening threshold and the susceptibility to damage of the materials under investigation. Analysis of the results, together with numerical modeling, has revealed the important role of shock waves in the damage processes. It has been shown that a so-called integral damage factor may be used only within restricted ranges of the irradiation parameters. It has also been found that in the irradiation regime with well-developed gasdynamic motion of secondary plasma, the overall amount of radiation energy is spent preferentially either on removing large masses of cool matter from the material surface or on heating a small amount of plasma to high temperature (and, consequently, imparting to it a high velocity), depending on the power flux density and characteristics of the pulsed irradiation.
url http://dx.doi.org/10.1063/5.0005852
work_keys_str_mv AT vagribkov applicationofdenseplasmafocusdevicesandlasersintheradiationmaterialsciencesforthegoalsofinertialfusionbeyondignition
AT ivborovitskaya applicationofdenseplasmafocusdevicesandlasersintheradiationmaterialsciencesforthegoalsofinertialfusionbeyondignition
AT evdemina applicationofdenseplasmafocusdevicesandlasersintheradiationmaterialsciencesforthegoalsofinertialfusionbeyondignition
AT eekazilin applicationofdenseplasmafocusdevicesandlasersintheradiationmaterialsciencesforthegoalsofinertialfusionbeyondignition
AT svlatyshev applicationofdenseplasmafocusdevicesandlasersintheradiationmaterialsciencesforthegoalsofinertialfusionbeyondignition
AT samaslyaev applicationofdenseplasmafocusdevicesandlasersintheradiationmaterialsciencesforthegoalsofinertialfusionbeyondignition
AT vnpimenov applicationofdenseplasmafocusdevicesandlasersintheradiationmaterialsciencesforthegoalsofinertialfusionbeyondignition
AT tlaas applicationofdenseplasmafocusdevicesandlasersintheradiationmaterialsciencesforthegoalsofinertialfusionbeyondignition
AT mpaduch applicationofdenseplasmafocusdevicesandlasersintheradiationmaterialsciencesforthegoalsofinertialfusionbeyondignition
AT svrogozhkin applicationofdenseplasmafocusdevicesandlasersintheradiationmaterialsciencesforthegoalsofinertialfusionbeyondignition
_version_ 1724498570742071296

Similar Items