T. Levato scite author profile

This article appeared in a journal published by Elsevier. The attached copy is furnished to the author for internal non-commercial research and education use, including for instruction at the authors institution and sharing with colleagues.Other uses, including reproduction and distribution, or selling or licensing copies, or posting to personal, institutional or third party websites are prohibited. t r a c tA new facility named SPARC_LAB has been recently launched at the INFN National Laboratories in Frascati, merging the potentialities of the former projects SPARC and PLASMONX. We describe in this paper the status and the future perspectives at the SPARC_LAB facility.

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ELIMAIA: A Laser-Driven Ion Accelerator for Multidisciplinary Applications

Margarone

Cirrone

Cuttone

et al. 2018

QuBS

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The main direction proposed by the community of experts in the field of laser-driven ion acceleration is to improve particle beam features (maximum energy, charge, emittance, divergence, monochromaticity, shot-to-shot stability) in order to demonstrate reliable and compact approaches to be used for multidisciplinary applications, thus, in principle, reducing the overall cost of a laser-based facility compared to a conventional accelerator one and, at the same time, demonstrating innovative and more effective sample irradiation geometries. The mission of the laser-driven ion target area at ELI-Beamlines (Extreme Light Infrastructure) in Dolní Břežany, Czech Republic, called ELI Multidisciplinary Applications of laser-Ion Acceleration (ELIMAIA) , is to provide stable, fully characterized and tuneable beams of particles accelerated by Petawatt-class lasers and to offer them to the user community for multidisciplinary applications. The ELIMAIA beamline has been

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Generation of high pressure shocks relevant to the shock-ignition intensity regime

Batani

Antonelli

Atzeni

et al. 2014

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An experiment was performed using the PALS laser to study laser-target coupling and laser-plasma interaction in an intensity regime 1016 W/cm2, relevant for the “shock ignition” approach to Inertial Confinement Fusion. A first beam at low intensity was used to create an extended preformed plasma, and a second one to create a strong shock. Pressures up to 90 Megabars were inferred. Our results show the importance of the details of energy transport in the overdense region

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Recent results from experimental studies on laser–plasma coupling in a shock ignition relevant regime

Koester

Antonelli

Atzeni

et al. 2013

Plasma Phys. Control. Fusion

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Shock ignition (SI) is an appealing approach in the inertial confinement scenario for the ignition and burn of a pre-compressed fusion pellet. In this scheme, a strong converging shock is launched by laser irradiation at an intensity I λ 2 >10 15 W cm −2 µm 2 at the end of the compression phase. In this intensity regime, laser-plasma interactions are characterized by the onset of a variety of instabilities, including stimulated Raman scattering, Brillouin scattering and the two plasmon decay, accompanied by the generation of a population of fast electrons. The effect of the fast electrons on the efficiency of the shock wave production is investigated in a series of dedicated experiments at the Prague Asterix Laser Facility (PALS).We study the laser-plasma coupling in a SI relevant regime in a planar geometry by creating an extended preformed plasma with a laser beam at ∼7 × 10 13 W cm −2 (250 ps, 1315 nm). A strong shock is launched by irradiation with a second laser beam at intensities in the range 10 15 -10 16 W cm −2 (250 ps, 438 nm) at various delays with respect to the first beam. The pre-plasma is characterized using x-ray spectroscopy, ion diagnostics and interferometry. Spectroscopy and calorimetry of the backscattered radiation is performed in the spectral range 250-850 nm, including (3/2)ω, ω and ω/2 emission. The fast electron production is characterized through spectroscopy and imaging of the Kα emission. Information on the shock pressure is obtained using shock breakout chronometry and measurements of the craters produced by the shock in a massive target.Preliminary results show that the backscattered energy is in the range 3-15%, mainly due to backscattered light at the laser wavelength (438 nm), which increases with increasing the delay between the two laser beams. The values of the peak shock pressures inferred from the shock breakout times are lower than expected from 2D numerical simulations. The same simulations reveal that the 2D effects play a major role in these experiments, with the laser spot size comparable with the distance between critical and ablation layers.

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Electron radiography using a table-top laser-cluster plasma accelerator

Bussolino¹,

Faenov²,

Giulietti³

et al. 2013

J. Phys. D: Appl. Phys.

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Characterization of supersonic and subsonic gas targets for laser wakefield electron acceleration experiments

Lorenz

Grittani

Chacon‐Golcher

et al. 2019

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An integrated approach to ultraintense laser sciences: The PLASMON-X project

Gizzi

Bacci

Betti

et al. 2009

Eur. Phys. J. Spec. Top.

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Laser beam coupling with capillary discharge plasma for laser wakefield acceleration applications

Bagdasarov

Sasorov

Gasilov

et al. 2017

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One of the most robust methods, demonstrated to date, of accelerating electron beams by laser-plasma sources is the utilization of plasma channels generated by the capillary discharges. Although the spatial structure of the installation is simple in principle, there may be some important effects caused by the open ends of the capillary, by the supplying channels etc., which require a detailed 3D modeling of the processes. In the present work, such simulations are performed using the code MARPLE. First, the process of capillary filling with cold hydrogen before the discharge is fired, through the side supply channels is simulated. Second, the simulation of the capillary discharge is performed with the goal to obtain a time-dependent spatial distribution of the electron density near the open ends of the capillary as well as inside the capillary. Finally, to evaluate the effectiveness of the beam coupling with the channeling plasma wave guide and of the electron acceleration, modeling of the laser-plasma interaction was performed with the code INF&RNO.

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T. Levato

SPARC_LAB present and future

ELIMAIA: A Laser-Driven Ion Accelerator for Multidisciplinary Applications

Generation of high pressure shocks relevant to the shock-ignition intensity regime

Recent results from experimental studies on laser–plasma coupling in a shock ignition relevant regime

Electron radiography using a table-top laser-cluster plasma accelerator

Characterization of supersonic and subsonic gas targets for laser wakefield electron acceleration experiments

An integrated approach to ultraintense laser sciences: The PLASMON-X project

Laser beam coupling with capillary discharge plasma for laser wakefield acceleration applications

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