Your search keyword '"J. Gazave"' showing total 3 results

1. Characterisation of a MeV Bremsstrahlung x-ray source produced from a high intensity laser for high areal density object radiography

Author

R. Edwards, A. Compant La Fontaine, Christian Courtois, L. Le Dain, Nicolas Pichoff, J. Gazave, S. Bazzoli, J. L. Bourgade, O. Landoas, G. Pien, D. Mastrosimone, J. M. Lagrange, C. Aedy, and Christian Stoeckl

Subjects

Physics, Point spread function, Spectrometer, business.industry, Astrophysics::High Energy Astrophysical Phenomena, Monte Carlo method, Bremsstrahlung, Condensed Matter Physics, Laser, law.invention, Full width at half maximum, Optics, law, Optical transfer function, Plasma diagnostics, business

Abstract

Results of an experiment to characterise a MeV Bremsstrahlung x-ray emission created by a short (

Published

2013

2. High-resolution multi-MeV x-ray radiography using relativistic laser-solid interaction

Author

M. Fox, N. Sircombe, L. Le Dain, L. Biddle, J. M. Lagrange, Christian Courtois, R. Edwards, S. Bazzoli, Erik Lefebvre, D. Brebion, K. Thorp, D. Mastrosimone, A. Simons, Christian Stoeckl, A. Compant La Fontaine, J. L. Bourgade, D. Drew, O. Landoas, M. Ramsay, M. Barbotin, C. Aedy, G. Pien, M. Gardner, Nicolas Pichoff, and J. Gazave

Subjects

Physics, business.industry, Astrophysics::High Energy Astrophysical Phenomena, Bremsstrahlung, Particle accelerator, Electron, Condensed Matter Physics, Laser, Electromagnetic radiation, law.invention, Optics, Relativistic plasma, law, Industrial radiography, Physics::Accelerator Physics, Emission spectrum, business

Abstract

When high intensity (≥1019 W cm−2) laser light interacts with matter, multi-MeV electrons are produced. These electrons can be utilized to generate a MeV bremsstrahlung x-ray emission spectrum as they propagate into a high-Z solid target positioned behind the interaction area. The short duration (

Published

2011

3. Diagnostics hardening for harsh environment in Laser Mégajoule (invited)

Author

A. Richard, Laurent Videau, I. Masclet-Gobin, J.L. Leray, P. Troussel, G. Soullié, J. P. Seaux, T. Caillaud, F. J. Marshall, R. Maroni, I. Thfoin, G. Pien, Stéphane Darbon, J. L. Miquel, C. Chollet, R. Rosch, J. Raimbourg, Christian Stoeckl, Sylvain Girard, D. Rubin de Cervens, J. P. Jadaud, J. Gazave, J. L. Bourgade, J. Baggio, V. Y. Glebov, J. Legendre, P. Combis, W. Shmayda, O. Landoas, F. Aubard, S. Bazzoli, L. Disdier, Paul A. Jaanimagi, B. Villette, Craig Sangster, R. Marmoret, Y. Le Tonqueze, D. Gontier, D. D. Meyerhofer, J. C. Gomme, H. P. Jacquet, Florian Bonneau, C. Reverdin, C. Zuber, and J. Y. Boutin

Subjects

Physics, Optics, business.industry, Systems engineering, business, Instrumentation, Laser Mégajoule

Abstract

The diagnostic designs for the Laser Megajoule (LMJ) will require components to operate in environments far more severe than those encountered in present facilities. This harsh environment will be induced by fluxes of neutrons, gamma rays, energetic ions, electromagnetic radiations, and, in some cases, debris and shrapnel, at levels several orders of magnitude higher than those experienced today on existing facilities. The lessons learned about the vulnerabilities of present diagnostic parts fielded mainly on OMEGA for many years, have been very useful guide for the design of future LMJ diagnostics. The present and future LMJ diagnostic designs including this vulnerability approach and their main mitigation techniques will be presented together with the main characteristics of the LMJ facility that provide for diagnostic protection.

Published

2008