Nuclear Quantum Effects in Two-temperature Hydrogen via Orbital-free DFT Path Integral MD
ORAL
Abstract
Among systems at extreme conditions, hydrogen is special: its small nuclear mass implicates significant nuclear quantum effects (NQEs). An increasingly important set of extreme-condition systems has electrons driven to temperature Te far from the ion temperature Ti. For such two-temperature hydrogen, we report path integral molecular dynamics calculations driven by state-of-the-art orbital-free DFT calculations for the electrons. When the ratio of the ionic thermal de Broglie wavelength to their mean distance is larger than about 0.35, the ionic radial distribution function is strongly affected by NQEs. Moreover, NQEs induce a substantial increase in both the ionic and electronic pressures.
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Presenters
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Sam Trickey
University of Florida
Authors
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Sam Trickey
University of Florida
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Dongdong Kang
Physics, National University of Defense Technology
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Kai Luo
Geophysical Laboratory, Carnegie Institution for Science, Geophysical Laboratory, Carnegie Institution of Washington, Geophysical Laboratory, Carnegie Institution of Science
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Valentin Karasiev
Laboratory for Laser Energetics, University of Rochester, NY, Laboratory for Laser Energetics, Univ. of Rochester
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Keith Runge
Univ of Arizona, Materials Science and Engineering, Univ. of Arizona