Interaction of powerful hot plasma and fast ion streams with materials in dense plasma focus devices

0472591 - ÚFP 2017 RIV CH eng J - Journal Article
Chernyshova, M. - Gribkov, V. A. - Kowalska-Strzeciwilk, E. - Kubkowska, M. - Miklaszewski, R. - Paduch, M. - Pisarczyk, T. - Zielinska, E. - Demina, E.V. - Pimenov, V. N. - Maslyaev, S. A. - Bondarenko, G.G. - Vilémová, Monika - Matějíček, Jiří
Interaction of powerful hot plasma and fast ion streams with materials in dense plasma focus devices.
Fusion Engineering and Design. Roč. 113, December (2016), s. 109-118. ISSN 0920-3796. E-ISSN 1873-7196
R&D Projects: GA ČR(CZ) GA14-12837S
Institutional support: RVO:61389021
Keywords : Radiation damageability * Materials tests * Plasma focus * Plasma streams * Ion beams * Laser interferometrya
OECD category: Nuclear related engineering
Impact factor: 1.319, year: 2016
http://www.sciencedirect.com/science/article/pii/S0920379616306858

A process of irradiating and ablating solid-state targets with hot plasma and fast ion streams in two Dense Plasma Focus (DPF) devices - PF-6 and PF-1000 was examined by applying a number of diagnostics of nanosecond time resolution. Materials perspective for use in chambers of the mainstream nuclear fusion facilities (mainly with inertial plasma confinement like NIF and Z-machine), intended both for the first wall and for constructions, have been irradiated in these simulators. Optical microscopy, SEM, Atomic Emission Spectroscopy, images in secondary electrons and in characteristic X-ray luminescence of different elements, and X-ray elemental analysis, gave results on damageability for a number of materials including low-activated ferritic and austenitic stainless steels, beta-alloy of Ti, as well as two types of W and a composite on its base. With an increase of the number of shots irradiating the surface, its morphology changes from weakly pronounced wave-like structures or ridges to strongly developed ones. At later stages, due to the action of the secondary plasma produced near the target materials they melted, yielding both blisters and a fracturing pattern: first along the grain and then "in-between" the grains creating an intergranular net of microcracks. At the highest values of power flux densities multiple bubbles appeared. Furthermore, in this last case the cracks were developed because of microstresses at the solidification of melt. Presence of deuterium within the irradiated ferritic steel surface nanolayers is explained by capture of deuterons in lattice defects of the types of impurity atoms, pores and oxycarbonitride particles existed in the material.
Permanent Link: http://hdl.handle.net/11104/0269858