Hydrodynamic model for picosecond propagation of laser-created nanoplasmas

Saxena, Vikrant; Ziaja, Beata; Jurek, Zoltan; Santra, Robin

doi:10.1016/j.hedp.2015.04.002

Journal Article

PUBDB-2015-02185

Hydrodynamic model for picosecond propagation of laser-created nanoplasmas

Saxena, V. (Corresponding author)CFEL*DESY* ; Jurek, Z.CFEL*DESY* ; Ziaja, B. (Corresponding author)CFEL*DESY* ; Santra, R.CFEL*DESY*

2015
Elsevier Amsterdam [u.a.]

High energy density physics 15, 93 - 98 (2015) [10.1016/j.hedp.2015.04.002]

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Please use a persistent id in citations: doi:10.1016/j.hedp.2015.04.002

Abstract: The interaction of a free-electron-laser pulse with a moderate or large size cluster is known to create a quasi-neutral nanoplasma, which then expands on hydrodynamic timescale, i.e., >1>1 ps. To have a better understanding of ion and electron data from experiments derived from laser-irradiated clusters, one needs to simulate cluster dynamics on such long timescales for which the molecular dynamics approach becomes inefficient. We therefore propose a two-step Molecular Dynamics-Hydrodynamic scheme. In the first step we use molecular dynamics code to follow the dynamics of an irradiated cluster until all the photo-excitation and corresponding relaxation processes are finished and a nanoplasma, consisting of ground-state ions and thermalized electrons, is formed. In the second step we perform long-timescale propagation of this nanoplasma with a computationally efficient hydrodynamic approach.In the present paper we examine the feasibility of a hydrodynamic two-fluid approach to follow the expansion of spherically symmetric nanoplasma, without accounting for the impact ionization and three-body recombination processes at this stage. We compare our results with the corresponding molecular dynamics simulations. We show that all relevant information about the nanoplasma propagation can be extracted from hydrodynamic simulations at a significantly lower computational cost when compared to a molecular dynamics approach. Finally, we comment on the accuracy and limitations of our present model and discuss possible future developments of the two-step strategy.

Classification:

ddc:530

Note: (c) Elsevier Ltd.

Contributing Institute(s):

CFEL-Theory (FS-CFEL-3)

Research Program(s):

6211 - Extreme States of Matter: From Cold Ions to Hot Plasmas (POF3-621) (POF3-621)

Experiment(s):

No specific instrument

Appears in the scientific report 2015

Database coverage:
Embargoed OpenAccess

;

; Current Contents - Physical, Chemical and Earth Sciences ; IF < 5 ; JCR ; SCOPUS ; Science Citation Index Expanded ; Thomson Reuters Master Journal List ; Web of Science Core Collection

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Private Collections > >DESY > >FS > FS-CFEL-3
Document types > Articles > Journal Article
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OpenAccess

Record created 2015-06-03, last modified 2025-07-30

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