Density evolution of a copper wire during nanosecond timescale underwater explosions

M. Nitishinskiy; A. Virozub; A. Rososhek; D. Yanuka; Ya E. Krasik

doi:10.1063/1.5047566

Density evolution of a copper wire during nanosecond timescale underwater explosions

M. Nitishinskiy, A. Virozub, A. Rososhek, D. Yanuka, Ya E. Krasik

Physics

Research output: Contribution to journal › Article › peer-review

Abstract

We present high-contrast X-ray images (∼30 μm space and ∼10 ns time resolution) of ns-timescale underwater electrical explosions of copper wires to the low density limit of ∼1 g/cm³, using a rod-ring electron diode as a source of X-rays. The radial density distribution, obtained by inverse Abel transform analysis of the X-ray images, is reproduced by one dimensional magneto-hydrodynamic (MHD) simulations using the SESAME equations of state and a modified Bakulin, Kuropatenko, and Luchinskii conductivity model for copper. These modifications are introduced by matching the experimental and simulated current and voltage waveforms and the radial wire expansion. For our ns-timescale copper wire underwater electrical explosions, the X-ray images display no MHD and thermal instabilities.

Original language	English
Article number	092709
Journal	Physics of Plasmas
Volume	25
Issue number	9
DOIs	https://doi.org/10.1063/1.5047566
State	Published - 1 Sep 2018

ASJC Scopus subject areas

Condensed Matter Physics

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title = "Density evolution of a copper wire during nanosecond timescale underwater explosions",

abstract = "We present high-contrast X-ray images (∼30 μm space and ∼10 ns time resolution) of ns-timescale underwater electrical explosions of copper wires to the low density limit of ∼1 g/cm3, using a rod-ring electron diode as a source of X-rays. The radial density distribution, obtained by inverse Abel transform analysis of the X-ray images, is reproduced by one dimensional magneto-hydrodynamic (MHD) simulations using the SESAME equations of state and a modified Bakulin, Kuropatenko, and Luchinskii conductivity model for copper. These modifications are introduced by matching the experimental and simulated current and voltage waveforms and the radial wire expansion. For our ns-timescale copper wire underwater electrical explosions, the X-ray images display no MHD and thermal instabilities.",

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AU - Nitishinskiy, M.

AU - Virozub, A.

AU - Rososhek, A.

AU - Yanuka, D.

AU - Krasik, Ya E.

PY - 2018/9/1

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N2 - We present high-contrast X-ray images (∼30 μm space and ∼10 ns time resolution) of ns-timescale underwater electrical explosions of copper wires to the low density limit of ∼1 g/cm3, using a rod-ring electron diode as a source of X-rays. The radial density distribution, obtained by inverse Abel transform analysis of the X-ray images, is reproduced by one dimensional magneto-hydrodynamic (MHD) simulations using the SESAME equations of state and a modified Bakulin, Kuropatenko, and Luchinskii conductivity model for copper. These modifications are introduced by matching the experimental and simulated current and voltage waveforms and the radial wire expansion. For our ns-timescale copper wire underwater electrical explosions, the X-ray images display no MHD and thermal instabilities.

AB - We present high-contrast X-ray images (∼30 μm space and ∼10 ns time resolution) of ns-timescale underwater electrical explosions of copper wires to the low density limit of ∼1 g/cm3, using a rod-ring electron diode as a source of X-rays. The radial density distribution, obtained by inverse Abel transform analysis of the X-ray images, is reproduced by one dimensional magneto-hydrodynamic (MHD) simulations using the SESAME equations of state and a modified Bakulin, Kuropatenko, and Luchinskii conductivity model for copper. These modifications are introduced by matching the experimental and simulated current and voltage waveforms and the radial wire expansion. For our ns-timescale copper wire underwater electrical explosions, the X-ray images display no MHD and thermal instabilities.

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Density evolution of a copper wire during nanosecond timescale underwater explosions

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