Gianluca Gregori

Numerical modeling of laser-driven experiments aiming to demonstrate magnetic field amplification via turbulent dynamo

(2017)

Authors:

P Tzeferacos, A Rigby, A Bott, AR Bell, R Bingham, A Casner, F Cattaneo, EM Churazov, J Emig, N Flocke, F Fiuza, CB Forest, J Foster, C Graziani, J Katz, M Koenig, C-K Li, J Meinecke, R Petrasso, H-S Park, BA Remington, JS Ross, D Ryu, D Ryutov, K Weide, TG White, B Reville, F Miniati, AA Schekochihin, DH Froula, G Gregori, DQ Lamb

A strong diffusive ion mode in dense ionized matter predicted by Langevin dynamics

Nature Communications Springer Nature 8 (2017) 14125

Authors:

Paul Mabey, S Richardson, TG White, LB Fletcher, SH Glenzer, NJ Hartley, J Vorberger, DO Gericke, Gianluca Gregori

Abstract:

The state and evolution of planets, brown dwarfs and neutron star crusts is determined by the properties of dense and compressed matter. Due to the inherent difficulties in modelling strongly coupled plasmas, however, current predictions of transport coefficients differ by orders of magnitude. Collective modes are a prominent feature, whose spectra may serve as an important tool to validate theoretical predictions for dense matter. With recent advances in free electron laser technology, X-rays with small enough bandwidth have become available, allowing the investigation of the low-frequency ion modes in dense matter. Here, we present numerical predictions for these ion modes and demonstrate significant changes to their strength and dispersion if dissipative processes are included by Langevin dynamics. Notably, a strong diffusive mode around zero frequency arises, which is not present, or much weaker, in standard simulations. Our results have profound consequences in the interpretation of transport coefficients in dense plasmas.

Scaled laboratory experiments explain the kink behaviour of the Crab Nebula jet

Nature Communications Nature Publishing Group (2016)

Authors:

CK Li, P Tzeferacos, D Lamb, Gianluca Gregori, PA Norreys, MJ Rosenberg, RK Follett, DH Froula, M Koenig, FH Seguin, JA Frenje, HG Rinderknecht, H Sio, AB Zylstra, RD Petrasso, PA Amendt, HS Park, BA Remington, DD Ryutov, SC Wilks, R Betti, A Frank, SX Hu, TC Sangster, P Hartigan

Abstract:

The remarkable discovery by the Chandra X-ray observatory that the Crab nebula's jet periodically changes direction provides a challenge to our understanding of astrophysical jet dynamics. It has been suggested that this phenomenon may be the consequence of magnetic fields and magnetohydrodynamic instabilities, but experimental demonstration in a controlled laboratory environment has remained elusive. Here we report experiments that use high-power lasers to create a plasma jet that can be directly compared with the Crab jet through well-defined physical scaling laws. The jet generates its own embedded toroidal magnetic fields; as it moves, plasma instabilities result in multiple deflections of the propagation direction, mimicking the kink behaviour of the Crab jet. The experiment is modelled with three-dimensional numerical simulations that show exactly how the instability develops and results in changes of direction of the jet.

QED-driven laser absorption

(2016)

Authors:

MC Levy, TG Blackburn, N Ratan, J Sadler, CP Ridgers, M Kasim, L Ceurvorst, J Holloway, MG Baring, AR Bell, SH Glenzer, G Gregori, A Ilderton, M Marklund, M Tabak, SC Wilks

Short-pulse laser-driven x-ray radiography

High Power Laser Science and Engineering Cambridge University Press 4 (2016) e30

Authors:

E Brambrink, S Baton, M Koenig, R Yurchak, N Bidaut, B Albertazzi, JE Cross, Gianluca Gregori, Alexandra Rigby, E Falize, A Pelka, F Kroll, S Pikuz, Y Sakawa, N Ozaki, C Kuranz, M Manuel, C Li, P Tzeferacos, D Lamb

Abstract:

We have developed a new radiography setup with a short-pulse laser-driven x-ray source. Using a radiography axis perpendicular to both long- and short-pulse lasers allowed optimizing the incident angle of the short-pulse laser on the x-ray source target. The setup has been tested with various x-ray source target materials and different laser wavelengths. Signal to noise ratios are presented as well as achieved spatial resolutions. The high quality of our technique is illustrated on a plasma flow radiograph obtained during a laboratory astrophysics experiment on POLARs.