1. Modeling Planetary Interiors in Laser Based Experiments Using Shockless Compression
- Author
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J. S. Wark, Daniel H. Kalantar, James S. Stolken, Jon Eggert, Hector Lorenzana, J. D. Colvin, K. Rosolankova, Bruce Remington, S. W. Pollaine, and James Hawreliak
- Subjects
Diffraction ,Physics ,business.industry ,Astronomy and Astrophysics ,Laser ,Compression (physics) ,Pulse (physics) ,Shock (mechanics) ,law.invention ,Optics ,Space and Planetary Science ,law ,High pressure ,X-ray crystallography ,business ,National Ignition Facility - Abstract
X-ray diffraction is a widely used technique for measuring the crystal structure of a compressed material. Recently, short pulse x-ray sources have been used to measure the crystal structure in-situ while a sample is being dynamically loaded. To reach the ultra high pressures that are unattainable in static experiments at temperatures lower than using shock techniques, shockless quasi-isentropic compression is required. Shockless compression has been demonstrated as a successful means of accessing high pressures. The National Ignition Facility (NIF), which will begin doing high pressure material science in 2010, it should be possible to reach over 2 TPa quasi-isentropically. This paper outlines how x-ray diffraction could be used to study the crystal structure in laser driven, shocklessly compressed targets the same way it has been used in shock compressed samples. A simulation of a shockless laser driven iron is used to generate simulated diffraction signals, and recent experimental results are presented.
- Published
- 2007