2014
DOI: 10.1103/physrevlett.112.055504
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Electron-Phonon Coupling and the Metallization of Solid Helium at Terapascal Pressures

Abstract: Solid He is studied in the pressure and temperature ranges 1-40 TPa and 0-10,000 K using firstprinciples methods. Anharmonic vibrational properties are calculated within a self-consistent field framework, including the internal and free energies, density-pressure relation, stress tensor, thermal expansion, and the electron-phonon coupling renormalization of the electronic band gap. We find that an accurate description of electron-phonon coupling requires us to use a non-perturbative approach. The metalization … Show more

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Cited by 77 publications
(86 citation statements)
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“…Many different numerical methods have been applied to solid helium [10][11][12] . The electronic subsystem can either be described from first principles, like in density functional theory (DFT)-based methods, or replaced by empirical pairwise or n-body interactions between nuclei.…”
Section: A Total Energy Calculationsmentioning
confidence: 99%
“…Many different numerical methods have been applied to solid helium [10][11][12] . The electronic subsystem can either be described from first principles, like in density functional theory (DFT)-based methods, or replaced by empirical pairwise or n-body interactions between nuclei.…”
Section: A Total Energy Calculationsmentioning
confidence: 99%
“…In semiconductors, the highly heterogeneous electron-phonon interactions (e.g. in polar semiconductors with Fröhlich interactions [9]) and, in some cases, the higher lattice thermal conductivity in comparison to metals weaken the hypothesis of a thermalized phononic subsystem [10,11], hence calling for the reexamination of the 2T physical picture in semiconductors.In this context, the advent of first-principles techniques able to predict the mode-and energy-resolved electronphonon [12][13][14] and phonon-phonon interactions [15,16] provides an important opportunity: In their modern implementations [13,16,17], these methods have been able to predict lattice thermal conductivities [18][19][20][21], the temperature-and pressure-dependence of the electronic bandgap [22][23][24][25][26][27][28], electrical conductivities [29,30], and hot carrier dynamics [31,32]. However, to the best of our knowledge and despite these early successes, these approaches have yet to be applied to the computation of electron-induced, non-equilibrium phonon distributions and their effects on thermal relaxation of electrons.…”
mentioning
confidence: 99%
“…23 It is critical to have a detailed knowledge of the band gap as this has a significant impact on our understanding of white dwarf cooling, and consequently in estimates of the age of the Universe.…”
mentioning
confidence: 99%