Laboratory astroparticle physics

The first experiments on the national ignition facility

J PHYS IV 133 (2006) 43-45

Authors:

OL Landen, S Glenzer, D Froula, E Dewald, LJ Suter, M Schneider, D Hinkel, J Fernandez, J Kline, S Goldman, D Braun, P Celliers, S Moon, H Robey, N Lanier, G Glendinning, B Blue, B Wilde, O Jones, J Schein, L Divol, D Kalantar, K Campbell, J Holder, J McDonald, C Niemann, A Mackinnon, R Collins, D Bradley, J Eggert, D Hicks, G Gregori, R Kirkwood, C Niemann, B Young, J Foster, F Hansen, T Perry, D Munro, H Baldis, G Grim, R Heeter, B Hegelich, D Montgomery, G Rochau, R Olson, R Turner, J Workman, R Berger, B Cohen, W Kruer, B Langdon, S Langer, N Meezan, H Rose, B Still, E Williams, E Dodd, J Edwards, MC Monteil, M Stevenson, B Thomas, R Coker, G Magelssen, P Rosen, P Stry, D Woods, S Weber, S Alvarez, G Armstrong, R Bahr, JL Bourgade, D Bower, J Celeste, M Chrisp, S Compton, J Cox, C Constantin, R Costa, J Duncan, A Ellis, J Emig, C Gautier, A Greenwood, R Griffith, F Holdner, G Holtmeier, D Hargrove, T James, J Kamperschroer, J Kimbrough, M Landon, D Lee, R Malone, M May, S Montelongo, J Moody, E Ng, A Nikitin, D Pellinen, K Piston, M Poole, V Rekow, M Rhodes, R Shepherd, S Shiromizu, D Voloshin, A Warrick, P Watts, F Weber, P Young, P Arnold, L Atherton, G Bardsley, R Bonanno, T Borger, M Bowers, R Bryant, S Buckman, S Burkhart, F Cooper, S Dixit, G Erbert, D Eder, B Ehrlich, B Felker, J Fornes, G Frieders, S Gardner, C Gates, M Gonzalez, S Grace, T Hall, C Haynam, G Heestand, M Henesian, M Hermann, G Hermes, S Huber, K Jancaitis, S Johnson, B Kauffman, T Kelleher, T Kohut, AE Koniges, T Labiak, D Latray, A Lee, D Lund, S Mahavandi, KR Manes, C Marshall, J McBride, T McCarville, L McGrew, J Menapace, E Mertens, D Munro, J Murray, J Neumann, M Newton, P Opsahl, E Padilla, T Parham, G Parrish, C Petty, M Polk, C Powell, I Reinbachs, R Rinnert, B Riordan, G Ross, V Robert, M Tobin, S Sailors, R Saunders, M Schmitt, M Shaw, M Singh, M Spaeth, A Stephens, G Tietbohl, J Tuck, B Van Wonterghem, R Vidal, P Wegner, P Whitman, K Williams, K Winward, K Work, R Wallace, A Nobile, M Bono, B Day, J Elliott, D Hatch, H Louis, R Manzenares, D O'Brien, P Papin, T Pierce, G Rivera, J Ruppe, D Sandoval, D Schmidt, L Valdez, K Zapata, B MacGowan, M Eckart, W Hsing, P Springer, B Hammel, E Moses, G Miller

Abstract:

A first set of shock propagation, laser-plasma interaction, hohlraum energetics and hydrodynamic experiments have been performed using the first 4 beams of the National Ignition Facility (NIF), in support of indirect drive Inertial Confinement Fusion (ICF) and High Energy Density Physics.

Hot surface ionic line emission and cold K-inner shell emission from petawatt-laser-irradiated Cu foil targets

Physics of Plasmas 13:4 (2006)

Authors:

W Theobald, K Akli, R Clarke, JA Delettrez, RR Freeman, S Glenzer, J Green, G Gregori, R Heathcote, N Izumi, JA King, JA Koch, J Kuba, K Lancaster, AJ MacKinnon, M Key, C Mileham, J Myatt, D Neely, PA Norreys, HS Park, J Pasley, P Patel, SP Regan, H Sawada, R Shepherd, R Snavely, RB Stephens, C Stoeckl, M Storm, B Zhang, TC Sangster

Abstract:

A hot, 2 to 3 keV electron temperature surface plasma was observed in the interaction of a 0.7 ps petawatt laser beam with solid copper-foil targets at intensities > 1020 W cm2. Copper K-shell spectra were measured in the range of 8 to 9 keV using a single-photon-counting x-ray charged-coupled-device camera. In addition to Kα and KΒ inner-shell lines, the emission contained the Cu Heα and Lyα lines, allowing the temperature to be inferred. These lines have not been observed previously with ultrafast laser pulses. For intensities less than 3× 1018 W cm2, only the Kα and KΒ inner-shell emissions are detected. Measurements of the absolute Kα yield as a function of the laser intensity are in general agreement with a model that includes refluxing and confinement of the suprathermal electrons in the target volume. © 2006 American Institute of Physics.

Limits on collective X-ray scattering imposed by coherence

Europhysics Letters 74:4 (2006) 637-643

Authors:

G Gregori, R Tommasini, OL Landen, RW Lee, SH Glenzer

Abstract:

We present the calculation of the threshold for observation of collective plasmon modes in a solid density plasma probed with a partially coherent X-ray source. We find that at lower electron densities (ne ≲ 2 × 1023 cm-3) de-coherence effects pose a stringent limit to the effective divergence as well as bandwidth of the probe source. These results are more restrictive than the usual condition that the probed scale-length must be larger than the screening distance in the plasma. © EDP Sciences.

Electron-density scaling of conversion efficiency of laser energy into L-shell X-rays

Journal of Quantitative Spectroscopy and Radiative Transfer 99:1-3 (2006) 186-198

Authors:

KB Fournier, C Constantin, CA Back, L Suter, HK Chung, MC Miller, DH Froula, G Gregori, SH Glenzer, EL Dewald, OL Landen

Abstract:

Laser-Produced plasmas at subcritical densities have proven to be efficient sources for X-ray production. In this context, we obtain experimental results from Kr and Xe gas-filled targets that were irradiated by the OMEGA (Laboratory for Laser Energetics, University of Rochester) laser. Nearly 40% of the laser energy was converted into X-rays in the L-shell-photon-energy range (≥ 1.6 keV) by a Kr-filled target. The conversion efficiency measurements were correlated with time-resolved plasma-temperature measurements done by means of a Thomson-scattering diagnostic. The measured range of temperatures, between 2-3.5 keV, is in good agreement with LASNEX radiation-hydrodynamics simulations. X-ray-cooling rates and charge-state distributions were computed using detailed atomic data from the HULLAC suite of codes. X-ray yields predicted by the cooling-rate calculations are compared to measured spectra, and good agreement is found for predictions made with highly-detailed atomic models. We find that X-ray conversion efficiency in Kr-filled targets is a strong function of temperature, and has an optimum density near 15% of the laser's critical density. © 2005 Elsevier Ltd. All rights reserved.

Measurement of carbon ionization balance in high-temperature plasma mixtures by temporally resolved X-ray scattering

Journal of Quantitative Spectroscopy and Radiative Transfer 99:1-3 (2006) 225-237

Authors:

G Gregori, SH Glenzer, HK Chung, DH Froula, RW Lee, NB Meezan, JD Moody, C Niemann, OL Landen, B Holst, R Redmer, SP Regan, H Sawada

Abstract:

We have measured carbon ionization balance in a multi-component plasma in the high-temperature, up to fully ionized, regime by spectrally resolved X-ray scattering. In particular, the measurements have been performed in an underdense (ne ≈ 1021 cm-3) 0.35- μm laser-produced plasma, containing a mixture of C, H with Al and Ar impurities, by using time-resolved back-scattered spectra from a 9.0 keV Zn He-α X-ray probe detected with a high-efficiency graphite Bragg crystal coupled to a framing camera. Measured values for the plasma temperature and carbon ionization state as well as impurity concentrations were obtained by fitting the Doppler-broadened and Compton-shifted scattered spectra at various times after the plasma heating with a modified X-ray form factor that includes the full effects of cross-correlation between different species. These data test collisional-radiative and radiation hydrodynamics modeling from cold (Te ≲ 5 eV) to fully ionized carbon (Te ∼ 280 eV).