A. Hauer scite author profile

We have used x-ray diffraction with subnanosecond temporal resolution to measure the lattice parameters of orthogonal planes in shock compressed single crystals of silicon (Si) and copper (Cu). Despite uniaxial compression along the (400) direction of Si reducing the lattice spacing by nearly 11%, no observable changes occur in planes with normals orthogonal to the shock propagation direction. In contrast, shocked Cu shows prompt hydrostaticlike compression. These results are consistent with simple estimates of plastic strain rates based on dislocation velocity data.

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First-principles equations of state for simulations of shock waves in silicon

Swift

Ackland

Hauer

et al. 2001

Phys. Rev. B

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Subnanosecond x-ray diffraction from laser-shocked crystals

et al. 1989

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Radiation drive in laser-heated hohlraums

Suter

Kauffman

Darrow

et al. 1996

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Nearly 10 years of Nova [E. M. Campbell, Laser Part. Beams 9, 209 (1991)] experiments and analysis have lead to a relatively detailed quantitative and qualitative understanding of radiation drive in laser-heated hohlraums. Our most successful quantitative modeling tool is two-dimensional (2-D) LASNEX numerical simulations [G. B. Zimmerman and W. L. Kruer, Comments Plasma Phys. Controlled Fusion 2, 51 (1975)]. Analysis of the simulations provides us with insight into the physics of hohlraum drive. In particular we find hohlraum radiation conversion efficiency becomes quite high with longer pulses as the accumulated, high-Z blow-off plasma begins to radiate. Extensive Nova experiments corroborate our quantitative and qualitative understanding.

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Lawson Criterion for Ignition Exceeded in an Inertial Fusion Experiment

Abu-Shawareb¹,

Acree²,

Adams³

et al. 2022

Phys. Rev. Lett.

208

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Shock launching in silicon studied with use of pulsed x-ray diffraction

et al. 1987

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Solid-state experiments at high pressure and strain rate

Kalantar

Remington

Colvin

et al. 2000

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Experiments have been developed using high powered laser facilities to study the response of materials in the solid state under extreme pressures and strain rates. Details of the target and drive development required for solid-state experiments and results from two separate experiments are presented. In the first, thin foils were compressed to a peak pressure of 180 GPa and accelerated. A pre-imposed modulation at the embedded Rayleigh–Taylor unstable interface was observed to grow. The growth rates were fluid-like at early time, but suppressed at later time. This result is suggestive of the theory of localized heating in shear bands, followed by conduction of the heat into the bulk material, allowing for recovery of the bulk material strength. In the second experiment, the response of Si was studied by dynamic x-ray diffraction. The crystal was observed to respond with uni-axial compression at a peak pressure 11.5–13.5 GPa.

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Direct Measurement of Compression of Laser-Imploded Targets Using X-Ray Spectroscopy

et al. 1977

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A. Hauer

Anomalous Elastic Response of Silicon to Uniaxial Shock Compression on Nanosecond Time Scales

First-principles equations of state for simulations of shock waves in silicon

Subnanosecond x-ray diffraction from laser-shocked crystals

Radiation drive in laser-heated hohlraums

Lawson Criterion for Ignition Exceeded in an Inertial Fusion Experiment

Shock launching in silicon studied with use of pulsed x-ray diffraction

Solid-state experiments at high pressure and strain rate

Direct Measurement of Compression of Laser-Imploded Targets Using X-Ray Spectroscopy

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