Short-pulse laser-driven x-ray radiography

Brambrink, E.; Baton, S. D.; Kœnig, M.; Yurchak, Roman; Bidaut, N.; Albertazzi, B.; Cross, J. E.; Gregori, G.; Rigby, A.; Falize, É.; Pełka, A.; Kroll, Florian; Pikuz, S. A.; Sakawa, Y.; Ozaki, Norimasa; Kuranz, C. C.; Manuel, M. J.-E.; Li, C.; Tzeferacos, Petros; Lamb, D. Q.

doi:10.1017/hpl.2016.31

Cited by 19 publications

(17 citation statements)

References 12 publications

(16 reference statements)

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“…Such targets require micromachining, precise assembly (embedded layers) and specific materials (doped brominated plastic). The Pico2000 beam is used in bottom-up geometry [67] to acquire snapshots of RTI during the linear and highly nonlinear phases. We are interested in accurate measurement of the mixing zone width in the nonlinear stage [68] .…”

Section: Experimental Setup and The First Radiographsmentioning

confidence: 99%

Turbulent hydrodynamics experiments in high energy density plasmas: scientific case and preliminary results of the TurboHEDP project

Casner

Rigon

Albertazzi

et al. 2018

High Pow Laser Sci Eng

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The physics of compressible turbulence in high energy density (HED) plasmas is an unchartered experimental area. Simulations of compressible and radiative flows relevant for astrophysics rely mainly on subscale parameters. Therefore, we plan to perform turbulent hydrodynamics experiments in HED plasmas (TurboHEDP) in order to improve our understanding of such important phenomena for interest in both communities: laser plasma physics and astrophysics. We will focus on the physics of supernovae remnants which are complex structures subject to fluid instabilities such as the Rayleigh-Taylor and Kelvin-Helmholtz instabilities. The advent of megajoule laser facilities, like the National Ignition Facility and the Laser Megajoule, creates novel opportunities in laboratory astrophysics, as it provides unique platforms to study turbulent mixing flows in HED plasmas. Indeed, the physics requires accelerating targets over larger distances and longer time periods than previously achieved. In a preparatory phase, scaling from experiments at lower laser energies is used to guarantee the performance of future MJ experiments. This subscale experiments allow us to develop experimental skills and numerical tools in this new field of research, and are stepping stones to achieve our objectives on larger laser facilities. We review first in this paper recent advances in high energy density experiments devoted to laboratory astrophysics. Then we describe the necessary steps forward to commission an experimental platform devoted to turbulent hydrodynamics on a megajoule laser facility. Recent novel experimental results acquired on LULI2000, as well as supporting radiative hydrodynamics simulations, are presented. Together with the development of LiF detectors as transformative X-ray diagnostics, these preliminary results are promising on the way to achieve micrometric spatial resolution in turbulent HED physics experiments in the near future.

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Section: Experimental Setup and The First Radiographsmentioning

confidence: 99%

Turbulent hydrodynamics experiments in high energy density plasmas: scientific case and preliminary results of the TurboHEDP project

Casner

Rigon

Albertazzi

et al. 2018

High Pow Laser Sci Eng

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“…The source is asymmetric for wire targets as the electrons are only restricted in the horizontal axis. Using the edge of a foil, or supported wire targets, has previously demonstrated 1D and 2D restriction of the X-ray source [11,16] . Figure 5(a) shows the horizontal axis measurement decreasing with decreasing target thickness, but when measuring the vertical source size we see a relatively constant response -the X-ray source measuring ∼60 µm irrespective of wire diameter.…”

Section: Spatial Emissionmentioning

confidence: 99%

“…High intensity laser pulses rapidly ionize and accelerate electrons in laser-solid interactions, driving a multi-megaampere current of relativistic electrons into the target [1][2][3] . This electron current produces a bright source of bremsstrahlung radiation as it propagates, which has long been used as a source for radiography [4][5][6][7][8][9][10][11] and as a diagnostic for the internal electron current [12][13][14][15] . In contrast to conventional sources of X-ray radiation, laser-driven sources are able to deliver a broad (keV to tens of MeV) range of energies in a duration on the order of the laser pulse (∼ps) from a small (<100 µm) source [6,16] .…”

Section: Introductionmentioning

confidence: 99%

Bremsstrahlung emission from high power laser interactions with constrained targets for industrial radiography

Armstrong

Brenner

Jones

et al. 2019

High Pow Laser Sci Eng

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Laser–solid interactions are highly suited as a potential source of high energy X-rays for nondestructive imaging. A bright, energetic X-ray pulse can be driven from a small source, making it ideal for high resolution X-ray radiography. By limiting the lateral dimensions of the target we are able to confine the region over which X-rays are produced, enabling imaging with enhanced resolution and contrast. Using constrained targets we demonstrate experimentally a $(20\pm 3)~\unicode[STIX]{x03BC}\text{m}$ X-ray source, improving the image quality compared to unconstrained foil targets. Modelling demonstrates that a larger sheath field envelope around the perimeter of the constrained targets increases the proportion of electron current that recirculates through the target, driving a brighter source of X-rays.

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“…Furthermore we do have a perfect control over the initial conditions, which are usually the consequences of numerical seeds in simulations [15]. Contrary to previous RTI laser plasma experiments performed over several years on larger scale facilities [23][24][25][26][27], the potential of short pulse driven x-ray radiography [28] allows, for the first time, one to acquire snapshots of RTI with unprecedented simultaneous spatial and temporal resolution. The RTI growth is measured until its nonlinear phase and the effect of the seed on the dynamic of RTI is quantified.…”

mentioning

confidence: 99%

“…The radiography is performed on the orthogonal axis to the wave vector of the modulation. The radiography was performed in a bottom-up geome-try in order to reduce noise due to relativistic electrons [28] on the detector (an imaging plate -IP). The titanium wire emits in principle x-ray centered on the K α line at 4.5 keV, but has a strong component of hard x-rays due to bremsstrahlung emission.…”

mentioning

confidence: 99%

Rayleigh-Taylor instability experiments on the LULI2000 laser in scaled conditions for young supernova remnants

Rigon¹,

Casner

Albertazzi³

et al. 2019

Phys. Rev. E

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We describe a platform developed on the LULI2000 laser facility to investigate the evolution of Rayleigh-Taylor instability (RTI) in scaled conditions relevant to young Supernovae Remnant (SNR) up to 200 years. An RT unstable interface is imaged with a short-pulse laser-driven (PICO2000) x-ray source, providing an unprecedented simultaneous high spatial (24 µm) and temporal (10 ps) resolution. This experiment provides relevant data to compare with astrophysical codes, as observational data on the development of RTI at the early stage of the SNR expansion are missing. A comparison is also performed with FLASH radiative magneto-hydrodynamic simulations.

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Short-pulse laser-driven x-ray radiography

Cited by 19 publications

References 12 publications

Turbulent hydrodynamics experiments in high energy density plasmas: scientific case and preliminary results of the TurboHEDP project

Turbulent hydrodynamics experiments in high energy density plasmas: scientific case and preliminary results of the TurboHEDP project

Bremsstrahlung emission from high power laser interactions with constrained targets for industrial radiography

Rayleigh-Taylor instability experiments on the LULI2000 laser in scaled conditions for young supernova remnants

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