Dynamic compression of materials: metallization of fluid hydrogen at high pressures

Nellis, W. J.

doi:10.1088/0034-4885/69/5/r05

Cited by 188 publications

(119 citation statements)

References 326 publications

(472 reference statements)

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“…Simulations have shown that using the SIS100 parameters, it is possible to compress solid hydrogen to a density of about 3g/cm 3 having a pressure of the order of 30 Mbar while the temperature remains low (about 10000 K) which are conditions expected at the interiors of the Gaint palnets. This experiment can also help to understand hydrogen metallization [10] problem.…”

Section: Multiple Reflection Of Cylindrical Shocks and The Laplas Schemementioning

confidence: 93%

High energy density physics studies using intense particle beams at the FAIR facility at Darmstadt

Tahir

Shutov²,

Piriz

et al. 2013

EPJ Web of Conferences

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Abstract. High Energy Density (HED) physics spans over numerous areas of basic and applied physics, for example, astrophysics, planetary physics, geophysics, inertial fusion and many others. During the past fifteen years, great progress has been made on the development of bunched intense particle beams that have emerged as a novel tool for studying HED physics. In this paper we present two experiment designs that have been worked out for HED physics studies at the Facility for Antiprotons and Ion Research (FAIR) at Darmstadt. This facility has entered into construction phase and will provide one of the largest and most powerful particle accelerators in the world.

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Section: Multiple Reflection Of Cylindrical Shocks and The Laplas Schemementioning

confidence: 93%

High energy density physics studies using intense particle beams at the FAIR facility at Darmstadt

Tahir

Shutov²,

Piriz

et al. 2013

EPJ Web of Conferences

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“…We assume that, when metallic hydrogen is produced, the molecular phase of liquid hydrogen transforms into the atomic phase [9] and only some atoms are later ionized.…”

Section: Metal-dielectric Transitionmentioning

confidence: 99%

“…A qualitative breakthrough in the studies of metallic hydrogen occurred after a number of experiments on shock compression of both molecular hydrogen in the liquid state and hydrogen and deuterium plasma. Those experiments showed that electric conductivity increased steeply for certain combinations of density, pressure, and temperature [4][5][6][7][8][9]. Specific values of these parameters depended on the initial state of hydrogen (i.e., the state before compression).…”

Section: Introductionmentioning

confidence: 99%

Metal-Dielectric Transition in Hydrogen

Shvets

Vlasenko

2008

Acta Phys. Pol. A

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The electrical resistivity of liquid metallic hydrogen at a temperature of 3000 K and a density of 0.35 mol/cm 3 is calculated. Hydrogen is considered as a three-component system consisting of electrons, protons, and neutral hydrogen atoms. The second order of perturbation theory in electron-proton and electron-atom interactions is used to determine the inverse relaxation time for electric conductivity. The Coulomb electron-electron interaction is taken into account in the random phase approximation and the exchange interaction and correlation of conductivity electrons are included in the local--field approximation. The model of hard spheres is used for the proton and atomic subsystems. The concentration of the electrically neutral atomic component proved to be significantly lower than the value assumed by the discoverers of metallic hydrogen.

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“…Material-strength changes and phase transitions occur on nanosecond time scales in impact experiments -on these short time scales, the response of materials can be remarkably different than expected when compared to slower loading. The different macroscopic dynamics observed under high load rates has inspired theories that attempt to predict the underlying rates of microscopic mechanisms responsible for the observed differences in behavior (for recent reviews, see [1][2][3][4][5]). …”

Section: Introductionmentioning

confidence: 99%

“…Mass velocities up to a few km/s are generated in single-shock, propellant-driven, flier-plate impact experiments [1][2][3]. Higher velocities have been generated in pulsed-laser and pulsed-plasma driven experiments up to 19 km/s [6], 30 km/s [4], and ~ 100 km/s [5]. Improving the temporal and velocity resolution of high-velocity measurements continues to be of interest as it will lead to improved data needed to better understand high strain rate processes.…”

Section: Introductionmentioning

confidence: 99%

Single-mode fiber, velocity interferometry

Krauter

Jacobson

Patterson

et al. 2011

Review of Scientific Instruments

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In this paper we describe a velocity interferometer system (a VISAR) based entirely on single-mode fiber optics. This paper includes a description of principles used in developing the single-mode velocity interferometry system (SMV). The SMV design is based on polarizationinsensitive components. Polarization adjusters are included to eliminate the effects of residual birefringence and polarization dependent losses in the interferometers. Characterization measurements and calibration methods needed for data analysis and a method of data analysis are described. Calibration is performed directly using tunable lasers.During development, we demonstrated its operation using exploding-foil bridge-wire fliers up to 200 m/s. In a final test, we demonstrated the SMV in a gas gun experiment up to 1.2 km/sec. As a basis for comparison in the gas gun experiment, we used another velocimetry technique that is also based on single mode fiber optics: photonic Doppler velocimetry (PDV).For the gas gun experiment, we split the light returned from a single target spot, and performed a direct comparison of the homodyne (SMV) and heterodyne (PDV) techniques concurrently. The two techniques had a negligible mean difference and a 1.5 % standard deviation in the 1 dimensional shock zone.Within one interferometer delay time after a sudden Doppler shift, an SMV unencumbered by multimode-fiber dispersion exhibits two color beats. These beats have the same period as PDV beats --this interference occurs between the "recently" shifted and "formerly un-shifted" paths within the interferometer. We believe that recognizing this identity between homodyne and heterodyne beats is novel in the shock-physics field. SMV includes the conveniences of optical fiber, while removing the time resolution limitations associated with multimode delivery fiber.2

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Dynamic compression of materials: metallization of fluid hydrogen at high pressures

Cited by 188 publications

References 326 publications

High energy density physics studies using intense particle beams at the FAIR facility at Darmstadt

High energy density physics studies using intense particle beams at the FAIR facility at Darmstadt

Metal-Dielectric Transition in Hydrogen

Single-mode fiber, velocity interferometry

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