Your search keyword '"N. C. Woolsey"' showing total 2 results

1. Experiments on hot and dense laser-produced plasmas

Author

D. Liedahl, R. W. Lee, A. Asfaw, Bernard Talin, L. Klein, Annette Calisti, Bruce Hammel, Christopher J. Keane, Siegfried Glenzer, N. C. Woolsey, J. C. Moreno, Christina Back, L. Godbert, Sandrine Ferri, Albert L. Osterheld, C. Mossé, Roland Stamm, and J. K. Nash

Subjects

Electron density, law, Chemistry, Radiative transfer, Electron temperature, Plasma diagnostics, Emission spectrum, Atomic physics, Laser, Inertial confinement fusion, Spectral line, law.invention

Abstract

Plasmas generated by irradiating targets with ∼20 kJ of laser energy are routinely created in inertial confinement fusion research. X-ray spectroscopy provides one of the few methods for diagnosing the electron temperature and electron density. For example, electron densities approaching 1024 cm−3 have been diagnosed by spectral linewidths. However, the accuracy of the spectroscopic diagnostics depends the population kinetics, the radiative transfer, and the line shape calculations. Analysis for the complex line transitions has recently been improved and accelerated by the use of a database where detailed calculations can be accessed rapidly and interactively. Examples of data from Xe and Ar doped targets demonstrate the current analytic methods. First we will illustrate complications that arise from the presence of a multitude of underlying spectral lines. Then, we will consider the Ar He-like 1s2(1S0)−1s3p(1P0) transition where ion dynamic effects may affect the profile. Here, the plasma conditions are ...

Published

1997

2. In situ x-ray diffraction from uniform radiation driven shocks in crystalline solids

Author

R. Cauble, J. S. Wark, N. C. Woolsey, and R. Lee

Subjects

Shock wave, Diffraction, Materials science, Silicon, business.industry, Astrophysics::High Energy Astrophysical Phenomena, Physics::Optics, chemistry.chemical_element, Radiation, Laser, law.invention, Shock (mechanics), Monocrystalline silicon, Optics, chemistry, law, X-ray crystallography, business

Abstract

An experiment to create highly uniform shocks in crystalline solids suitable for studying the thickness of shock fronts by in situ x-ray diffraction is described. A laser is used to create a soft x-ray radiation source. This radiation source heats a thin layer of the silicon crystal; the ablation of this layer produces a uniform near-one-megabar shock. We discuss how x-ray diffraction can be used to measure the shock front thickness from a uniformly shock compressed solid. The x-ray diffraction technique is described through previously measured experimental data and by comparison to simulated diffraction records.

Published

1996