Gianluca Gregori

X-ray scattering measurements of radiative heating and cooling dynamics.

Phys Rev Lett 101:4 (2008) 045003

Authors:

G Gregori, SH Glenzer, KB Fournier, KM Campbell, EL Dewald, OS Jones, JH Hammer, SB Hansen, RJ Wallace, OL Landen

Abstract:

Spectrally and time-resolved x-ray scattering is used to extract the temperature and charge state evolution in a near solid density carbon foam driven by a supersonic soft x-ray heat wave. The measurements show a rapid heating of the foam material (approximately 200 eV/ns) followed by a similarly fast decline in the electron temperature as the foam cools. The results are compared to an analytic power balance model and to results from radiation-hydrodynamics simulations. Finally, the combination of charge state and temperature extracted from this known density isochorically heated plasma is used to distinguish between dense plasma ionization balance models.

A reduced coupled-mode description for the electron-ion energy relaxation in dense matter

EPL 83:1 (2008)

Authors:

G Gregori, DO Gericke

Abstract:

We present a simplified model for the electron-ion energy relaxation in dense two-temperature systems that includes the effects of coupled collective modes. It also extends the standard Spitzer result to both degenerate and strongly coupled systems. Starting from the general coupled-mode description, we are able to solve analytically for the temperature relaxation time in warm dense matter and strongly coupled plasmas. This was achieved by decoupling the electron-ion dynamics and by representing the ion response in terms of the mode frequencies. The presented reduced model allows for a fast description of temperature equilibration within hydrodynamic simulations and an easy comparison for experimental investigations. For warm dense matter, both fluid and solid, the model gives a slower electron-ion equilibration than predicted by the classical Spitzer result. Copyright © EPLA, 2008.

Experimental characterization of picosecond laser interaction with solid targets.

Phys Rev E Stat Nonlin Soft Matter Phys 77:5 Pt 2 (2008) 056403

Authors:

D Jung, LA Gizzi, L Labate, D Neely, MM Notley, PP Rajeev, M Roth, G Gregori

Abstract:

We have characterized the plasma produced by a picosecond laser pulse using x-ray spectroscopy. High-resolution high-sensitivity spectra of K -shell emission from a Ti plasma have been obtained, showing a strong contribution from multiply ionized ions. Hydrodynamic and collisional-radiative codes are used to extract the plasma temperature and density from these measurements. We show that our measurements can provide benchmarks for particle-in-cell (PIC) simulations of preplasma conditions in ultraintense laser-matter interactions.

Laser heating of solid matter by light-pressure-driven shocks at ultrarelativistic intensities.

Phys Rev Lett 100:16 (2008) 165002

Authors:

KU Akli, SB Hansen, AJ Kemp, RR Freeman, FN Beg, DC Clark, SD Chen, D Hey, SP Hatchett, K Highbarger, E Giraldez, JS Green, G Gregori, KL Lancaster, T Ma, AJ MacKinnon, P Norreys, N Patel, J Pasley, C Shearer, RB Stephens, C Stoeckl, M Storm, W Theobald, LD Van Woerkom, R Weber, MH Key

Abstract:

The heating of solid targets irradiated by 5 x 10(20) W cm(-2), 0.8 ps, 1.05 microm wavelength laser light is studied by x-ray spectroscopy of the K-shell emission from thin layers of Ni, Mo, and V. A surface layer is heated to approximately 5 keV with an axial temperature gradient of 0.6 microm scale length. Images of Ni Ly(alpha) show the hot region has 100 G bar light pressure compresses the preformed plasma and drives a shock into the solid, heating a thin layer.

Laser heating of solid matter by light-pressure-driven shocks at ultrarelativistic intensities

Physical Review Letters 100:16 (2008)

Authors:

KU Akli, SB Hansen, AJ Kemp, RR Freeman, FN Beg, DC Clark, SD Chen, D Hey, SP Hatchett, K Highbarger, E Giraldez, JS Green, G Gregori, KL Lancaster, T Ma, AJ MacKinnon, P Norreys, N Patel, J Pasley, C Shearer, RB Stephens, C Stoeckl, M Storm, W Theobald, LD Van Woerkom, R Weber, MH Key

Abstract:

The heating of solid targets irradiated by 5×1020Wcm-2, 0.8 ps, 1.05μm wavelength laser light is studied by x-ray spectroscopy of the K-shell emission from thin layers of Ni, Mo, and V. A surface layer is heated to ∼5keV with an axial temperature gradient of 0.6μm scale length. Images of Ni Lyα show the hot region has ≤25μm diameter. These data are consistent with collisional particle-in-cell simulations using preformed plasma density profiles from hydrodynamic modeling which show that the >100Gbar light pressure compresses the preformed plasma and drives a shock into the solid, heating a thin layer. © 2008 The American Physical Society.