Laboratory astroparticle physics

Laboratory simulations of supernova shockwave propagation

ASTROPHYS SPACE SCI 298:1-2 (2005) 61-67

Authors:

JF Hansen, MJ Edwards, D Froula, G Gregori, A Edens, T Ditmire

Abstract:

Supernovae launch spherical shocks into the circumstellar medium (CSM). These shocks have high Mach numbers and may be radiative. We have created similar shocks in the laboratory by focusing laser pulses onto the tip of a solid pin surrounded by ambient gas; ablated material from the pin rapidly expands and launches a shock through the surrounding gas. Laser pulses were typically 5 ns in duration with ablative energies ranging from 1-150 J. Shocks in ambient gas pressures of similar to 1 kPa were observed at spatial scales of up to 5 cm using optical cameras with schlieren. Emission spectroscopy data were obtained to infer electron temperatures (< 10 eV).In this experiment we have observed a new phenomena; at the edge of the radiatively heated gas ahead of the shock, a second shock forms. The two expanding shocks are simultaneously visible for a time, until the original shock stalls from running into the heated gas. The second shock remains visible and continues to expand. A minimum condition for the formation of the second shock is that the original shock is super-critical, i.e., the temperature distribution ahead of the original shock has an inflexion point. In a non-radiative control experiment the second shock does not form. We hypothesize that a second shock could form in the astrophysical case, possibly in radiative supernova remnants such as SN1993J, or in shock-CSM interaction.

Intensity limits for propagation of 0.527 microm laser beams through large-scale-length plasmas for inertial confinement fusion.

Phys Rev Lett 94:8 (2005) 085005

Authors:

C Niemann, L Divol, DH Froula, G Gregori, O Jones, RK Kirkwood, AJ Mackinnon, NB Meezan, JD Moody, C Sorce, LJ Suter, R Bahr, W Seka, SH Glenzer

Abstract:

We have established the intensity limits for propagation of a frequency-doubled (2omega, 527 nm) high intensity interaction beam through an underdense large-scale-length plasma. We observe good beam transmission at laser intensities at or below 2x10(14) W/cm(2) and a strong reduction at intensities up to 10(15) W/cm(2) due to the onset of parametric scattering instabilities. We show that temporal beam smoothing by spectral dispersion allows a factor of 2 higher intensities while keeping the beam spray constant, which establishes frequency-doubled light as an option for ignition and burn in inertial confinement fusion experiments.

Experimental characterization of a strongly coupled solid density plasma generated in a short-pulse laser target interaction

Contributions to Plasma Physics 45:3-4 (2005) 284-292

Authors:

G Gregori, SB Hansen, R Clarke, R Heathcote, MH Key, J King, RI Klein, N Izumi, AJ Mackinnon, SJ Moon, HS Park, J Pasley, N Patel, PK Patel, BA Remington, DD Ryutov, R Shepherd, RA Snavely, SC Wilks, BB Zhang, SH Glenzer

Abstract:

We have measured high resolution copper Kα spectra from a picosecond high intensity laser produced plasma. By fitting the shape of the experimental spectra with a self-consistent-field model which includes all the relevant line shifts from multiply ionized atoms, we are able to infer time and spatially averaged electron temperatures (Te) and ionization state (Z) in the foil. Our results show increasing values for Te and Z when the overall mass of the target is reduced. In particular, we measure temperatures in excess of 200 eV with Z ∼ 13-14. For these conditions the ion-ion coupling constant is Γii ∼ 8-9, thus suggesting the achievement of a strongly coupled plasma regime. © 2005 WILEY-VCH Verlag GmbH & Co. KGaA, Weinheim.

Blue and green light? Wavelength scaling for NIF

Inertial Fusion Sciences and Applications 2003 (2004) 223-227

Authors:

W Kruer, J Moody, L Suter, S Glenzer, A MacKinnon, D Froula, G Gregori, L Divol, M Miller, R Bahr, W Seka, K Oades, RM Stevenson

Abstract:

Use of the National Ignition Facility to also output frequency-doubled (.53μm) laser light would allow significantly more energy to be delivered to targets as well as significantly greater bandwidth for beam smoothing. This green light option could provide access to new ICF target designs and a wider range of plasma conditions for other applications. The wavelength scaling of the laser plasma interaction physics is a key issue in assessing the green light option. Wavelength scaling theory based on the collisionless plasma approximation is explored, and some limitations associated with plasma collisionality are examined. Important features of the wavelength scaling are tested using the current experimental data base, which is growing. It appears that, with modest restrictions, .53μm light couples with targets as well as .35μm light does. A more quantitative understanding of the beneficial effects of SSD on the interaction physics is needed for both .53μm and .35μm light.

Electronic structure measurement of solid density plasmas using x-ray scattering

Inertial Fusion Sciences and Applications 2003 (2004) 902-906

Authors:

G Gregori, SH Glenzer, FJ Rogers, OL Landen, C Blancard, G Faussuriei, P Renaudin, S Kuhlbrodt, R Redmer

Abstract:

We present an improved analytical expression for the x-ray dynamic structure factor from a dense plasma which includes the effects of weakly bound electrons. This result can be applied to describe scattering from low to moderate Z plasmas, and it covers the entire range of plasma conditions that can be found in inertial confinement fusion experiments, from ideal to degenerate up to moderately coupled systems. We use our theory to interpret x-ray scattering experiments from solid density carbon plasma and to extract accurate measurements of electron temperature, electron density and charge state. We use our experimental results to validate various equation-of-state models for carbon plasmas.