Temporal and spatial dynamics of laser-induced aluminum plasma in argon background at atmospheric pressure: Interplay with the ambient gas

Temporal and spatial dynamics of laser-induced aluminum plasma in argon background at atmospheric pressure: Interplay with the ambient gas

Laser ablation in background gas implies supplementary complexities with respect to what happens in the vacuum. It is however essential to understand in detail the involved mechanisms for a number of applications requiring the ablation to be performed in an ambient gas at relative high pressure, suc...

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Veröffentlicht in:Spectrochimica acta. Part B: Atomic spectroscopy 2010-11, Vol.65 (11), p.896-907
Hauptverfasser: Ma, Q.L., Motto-Ros, V., Lei, W.Q., Boueri, M., Bai, X.S., Zheng, L.J., Zeng, H.P., Yu, J.
Format: Artikel
Sprache:eng
Schlagworte:
Abel inversion
Ablation
Aluminum
Ambient gas effects
Argon
Atmospheric pressure
Density
Fluid flow
Hydrodynamics
Laser-induced plasma
Local thermodynamic equilibrium
Plumes
Time- and space-resolved spectroscopy
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container_end_page 907
container_issue 11
container_start_page 896
container_title Spectrochimica acta. Part B: Atomic spectroscopy
container_volume 65
creator Ma, Q.L.
Motto-Ros, V.
Lei, W.Q.
Boueri, M.
Bai, X.S.
Zheng, L.J.
Zeng, H.P.
Yu, J.
description Laser ablation in background gas implies supplementary complexities with respect to what happens in the vacuum. It is however essential to understand in detail the involved mechanisms for a number of applications requiring the ablation to be performed in an ambient gas at relative high pressure, such as pulsed-laser deposition, or laser-induced breakdown spectroscopy. In this paper, the expansion of a vapor plume ablated from an aluminum target into an argon gas at atmospheric pressure is experimentally investigated using time- and space-resolved emission spectroscopy. The obtained results provide a detailed description of the interplay between the vapor and the gas. The electron density, the temperature and the number densities (and therefore the partial pressures) of aluminum vapor and argon gas have been measured in and surrounding the vapor plume. Our observations show a confinement of the vapor plume by the gas, which is expected as predicted by the usual hydrodynamics models. The result is a plasma core with quite uniform distributions in electron density, temperature and number densities. Such plasma core presents an ideal emission source for spectroscopic applications. It is however evidenced by our observations that a large amount of argon is mixed into the aluminum plume in the plasma core, which invalidates in the experimental conditions that we used, the hydrodynamic “piston” model where the background gas is pushed out by the shock wave surrounding the vapor plume. Instead, other mechanisms such as laser-supported detonation wave should play important roles in the early stage of the expansion of the plasma for the determination of its morphology at longer delays.
doi_str_mv 10.1016/j.sab.2010.08.005
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source Elsevier ScienceDirect Journals
subjects Abel inversion
Ablation
Aluminum
Ambient gas effects
Argon
Atmospheric pressure
Density
Fluid flow
Hydrodynamics
Laser-induced plasma
Local thermodynamic equilibrium
Plumes
Time- and space-resolved spectroscopy
title Temporal and spatial dynamics of laser-induced aluminum plasma in argon background at atmospheric pressure: Interplay with the ambient gas
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