Two-level ablation and damage morphology of Ru films under femtosecond extreme UV irradiation

Milov, I.; Zhakhovsky, V.; Ilnitsky, D.; Migdal, K.; Khokhlov, V.; Petrov, Y.; Inogamov, N.; Lipp, V.; Medvedev, Nikita; Ziaja, B.; Medvedev, V.; Makhotkin, I.A.; Louis, E.; Bijkerk, F.

doi:https://dx.doi.org/10.1016/j.apsusc.2020.146952

Number of the records: 1

Two-level ablation and damage morphology of Ru films under femtosecond extreme UV irradiation

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SYSNO ASEP	0540252
Document Type	J - Journal Article
R&D Document Type	Journal Article
Subsidiary J	Článek ve WOS
Title	Two-level ablation and damage morphology of Ru films under femtosecond extreme UV irradiation
Author(s)	Milov, I. (NL) Zhakhovsky, V. (RU) Ilnitsky, D. (RU) Migdal, K. (RU) Khokhlov, V. (RU) Petrov, Y. (RU) Inogamov, N. (RU) Lipp, V. (DE) Medvedev, Nikita (UFP-V)_ORCID Ziaja, B. (DE) Medvedev, V. (RU) Makhotkin, I.A. (NL) Louis, E. (NL) Bijkerk, F. (NL)
Number of authors	14
Article number	146952
Source Title	Applied Surface Science. - : Elsevier - ISSN 0169-4332 Roč. 528, October (2020), s. 1-18
Number of pages	18 s.
Language	eng - English
Country	NL - Netherlands
Keywords	Extreme ultraviolet ; Femtosecond laser ablation ; Free-electron laser ; Molecular dynamics ; Monte Carlo ; Thin films
Subject RIV	BL - Plasma and Gas Discharge Physics
OECD category	Fluids and plasma physics (including surface physics)
R&D Projects	LTT17015 GA MŠMT - Ministry of Education, Youth and Sports (MEYS)
	LM2015083 GA MŠMT - Ministry of Education, Youth and Sports (MEYS)
Method of publishing	Open access
Institutional support	UFP-V - RVO:61389021
UT WOS	000576740200009
EID SCOPUS	85087332352
DOI	10.1016/j.apsusc.2020.146952
Annotation	The dynamics of a thin ruthenium film irradiated by femtosecond extreme UV laser pulses is studied with a hybrid computational approach, which includes Monte Carlo, two-temperature hydrodynamics and molecular dynamics models. This approach is capable of accurate simulations of all stages of material evolution induced by extreme UV or X-ray photons: from nonequilibrium electron kinetics till complete lattice relaxation. We found that fast energy deposition in a subsurface layer leads to a two-level ablation: the top thin layer is ablated as a gas–liquid mixture due to expansion of overheated material at near and above critical conditions, whereas a thicker liquid layer below is ablated via a cavitation process. The latter occurs due to a thermo-mechanically induced tensile pressure wave. The liquid ablating layer exhibits unstable behaviour and disintegrates into droplets soon after detachment from the rest of the target. Our simulations reveal basic processes leading to formation of specific surface morphologies outside and inside the damage craters. The calculated ablation threshold, crater depth and morphological features are in quantitative agreement with the experimental data, which justifies the applicability of our hybrid model to study laser-induced material damage.
Workplace	Institute of Plasma Physics
Contact	Vladimíra Kebza, kebza@ipp.cas.cz, Tel.: 266 052 975
Year of Publishing	2021
Electronic address	https://www.sciencedirect.com/science/article/pii/S0169433220317098?via%3Dihub

Number of the records: 1