Electronic collective excitations in compressed lithium from<i>ab initio</i>calculations: Importance and anisotropy of local-field effects at large momenta

Errea, Ion; Rodríguez-Prieto, A.; Rousseau, Bruno; Silkin, Viatcheslav M.; Bergara, Aitor

doi:10.1103/physrevb.81.205105

Cited by 16 publications

(22 citation statements)

References 41 publications

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“…The presence of this type of plasmons strongly modifies the reflectivity, leading it to an almost vanishing value close to the plasmon energy. This anomalous optical behavior has been already observed in Na 22 and has been predicted in Li [23][24][25] and AlH 3 . 36 Thus, calcium seems to be another example of this behavior, providing a good example of how pressure-induced complexity is also reflected in the optical properties.…”

Section: Discussionsupporting

confidence: 78%

“…The inclusion of CLFEs does not significantly modify the plasmon energy position, similar to the interband plasmon found in fcc Li at small momenta. 25 Besides the remarkable low-energy plasmon, higher energy plasmons are also present in the sc phase of Ca. Although at 35 GPa we find two prominent peaks above 10 eV, one at 10.9 eV and the second at 13.1 eV, at the other pressures the second peak is not observed, and only a regular intraband plasmon is present.…”

Section: -5mentioning

confidence: 99%

“…22 Theoretical calculations describe a similar mitigation of the reflectivity for fcc lithium, 23 which is directly associated to the interband low-energy plasmon already predicted in previous ab initio calculations. [23][24][25] Indeed, in systems such as Ag, 26,27 graphite, 28 single-wall carbon nanotubes, 29 or MgB 2 , 30,31 interband transitions in the band structure shape the dielectric function of metals and induce the emergence of several plasmons that cannot be understood within the free-electron model. If the origin of a plasmon resides in these interband transitions, it is sometimes referred to in the literature as an interband plasmon.…”

Section: Introductionmentioning

confidence: 99%

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Optical properties of calcium under pressure from first-principles calculations

et al. 2012

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Here we present theoretical ab initio calculations based on time-dependent density-functional theory of the macroscopic dielectric function of calcium from 0 to 110 GPa in the fcc, bcc, and sc phases. All the dielectric functions are calculated using very fine reciprocal space meshes since both eigenvalues and matrix elements entering in the density-response functions are interpolated using Wannier functions. Our calculations correctly predict the energies of the low-and high-energy plasmons observed in the fcc phase at room pressure. Moreover, we predict that in the sc phase a very low-energy interband plasmon emerges at around 50 GPa that dramatically modifies the behavior of the reflectivity making it almost vanish at the plasmon energy. As a consequence, calcium becomes an example of how optical properties can become complex under pressure.

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Section: Discussionsupporting

confidence: 78%

Section: -5mentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

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Optical properties of calcium under pressure from first-principles calculations

et al. 2012

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“…Experimental evidence [3][4][5][6][7]9 shows that in the pressure and temperature ranges where the anomalous isotope effect was measured (15)(16)(17)(18)(19)(20)(21)(22)(23)(24)(25) GPa and below 30 K) lithium presents a fcc structure. At around 40 GPa, it transforms to the rhombohedral hR1 phase, which is just a distortion of the fcc phase along the c axis if one switches to a hexagonal representation.…”

Section: Introductionmentioning

confidence: 92%

Anharmonicity and the isotope effect in superconducting lithium at high pressures: A first-principles approach

et al. 2017

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Recent experiments1 have shown that lithium presents an extremely anomalous isotope effect in the 15-25 GPa pressure range. In this article we have calculated the anharmonic phonon dispersion of 7 Li and 6 Li under pressure, their superconducting transition temperatures, and the associated isotope effect. We have found a huge anharmonic renormalization of a transverse acoustic soft mode along ΓK in the fcc phase, the expected structure at the pressure range of interest. In fact, the anharmonic correction dynamically stabilizes the fcc phase above 25 GPa. However, we have not found any anomalous scaling of the superconducting temperature with the isotopic mass. Additionally, we have also analyzed whether the two lithium isotopes adopting different structures could explain the observed anomalous behavior. According to our enthalpy calculations including zero-point motion and anharmonicity it would not be possible in a stable regime.

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“…Although it could be expected to evolve to an even more free-electron like system with increasing pressure, it has been shown that pressure not only induces several structural transformations [2,3,4], but also gives rise to a plethora of fascinating physical properties [5] normally induced by nonlocality in the core pseudopotential with pressure [6,7]. For instance, lithium becomes a semiconductor near 80 GPa [8], it melts below ambient temperature (190 K) at around 50 GPa [2] and displays a periodic undamped plasmon according to theoretical calculations [9]. Moreover, it presents one of the highest superconducting critical temperatures (Tc) for an element, reaching values as high as 15 K at around 30 GPa [10][11][12][13].…”

Section: Introductionmentioning

confidence: 99%

Dynamical stability of face centered cubic lithium at 25 GPa

Borinaga¹,

Aseginolaza²,

Errea³

et al. 2017

Proc. 17th Int. Conf. On High Pressure in Semiconductor Physics &Amp; Workshop on High-Pressure Study on Superconducting

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We study the dynamical stability of face centered cubic lithium at 25 GPa within ab initio density functional theory calculations. The system shows an extremely softened transverse acoustic mode in the Γ-K high symmetry line, whose frequency is difficult to converge within a first-principles harmonic approach. We estimate the anharmonic correction of this value within the frozen phonon approximation assuming that the transverse acoustic mode only interacts with itself. By solving the Schrödinger equation for the potential energy curve and displacements along the vibrational mode of interest, we obtain the anharmonic eigenvalues and eigenfunctions. While the harmonic approach yields a phonon frequency of -28.6 cm -1 for this mode, anharmonicity renormalizes dramatically this value up to 115.3 cm -1 . Thus, anharmonic effects seem to dynamically stabilize this system.

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Electronic collective excitations in compressed lithium fromab initiocalculations: Importance and anisotropy of local-field effects at large momenta

Cited by 16 publications

References 41 publications

Optical properties of calcium under pressure from first-principles calculations

Optical properties of calcium under pressure from first-principles calculations

Anharmonicity and the isotope effect in superconducting lithium at high pressures: A first-principles approach

Dynamical stability of face centered cubic lithium at 25 GPa

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