Micron-scale resolution radiography of laser-accelerated and laser-exploded foils using an yttrium x-ray laser | Zendy

R. Cauble | Zendy; L.B. Da Silva | Zendy; T.W. Jr. Barbee | Zendy; P. M. Celliers | Zendy; J. C. Moreno | Zendy; Stanley Mrowka | Zendy; T. S. Perry | Zendy; A.S. Wan | Zendy

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Micron-scale resolution radiography of laser-accelerated and laser-exploded foils using an yttrium x-ray laser

Author(s) -

R. Cauble,

L.B. Da Silva,

T.W. Jr. Barbee,

P. M. Celliers,

J. C. Moreno,

Stanley Mrowka,

T. S. Perry,

A.S. Wan

Publication year - 1994

Publication title -

osti oai (u.s. department of energy office of scientific and technical information)

Language(s) - English

Resource type - Reports

DOI - 10.2172/71357

Subject(s) - filamentation , optics , laser , foil method , yttrium , materials science , rayleigh–taylor instability , beam (structure) , instability , physics , mechanics , metallurgy , composite material , oxide

The authors have imaged laser-accelerated foils and exploding foils on the few-micron scale using an yttrium x-ray laser (155 {angstrom}, 80 eV, {approximately}200 ps duration) and a multilayer mirror imaging system. At the maximum magnification of 30, resolution was of order one micron. The images were side-on radiographs of the foils. Accelerated foils showed significant filamentation on the rear-side (away from the driving laser) of the foil, although the laser beam was smoothed. In addition to the narrow rear-side filamentation, some shots revealed larger-scale plume-like structures on the front (driven) side of the Al foil. These plumes seem to be little-affected by beam smoothing and are likely a consequence of Rayleigh-Taylor instability. The experiments were carried out at the Nova two-beam facility

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