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Autores principales: Hellgren, Maria, Contant, Damian, Pitts, Thomas, Casula, Michele
Formato: Preprint
Publicado: 2022
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Acceso en línea:https://arxiv.org/abs/2205.01368
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author Hellgren, Maria
Contant, Damian
Pitts, Thomas
Casula, Michele
author_facet Hellgren, Maria
Contant, Damian
Pitts, Thomas
Casula, Michele
contents The high-pressure II-III phase transition in solid hydrogen is investigated using the random phase approximation and diffusion Monte Carlo. Good agreement between the methods is found confirming that an accurate treatment of exchange and correlation increases the transition pressure by more than 100 GPa with respect to semilocal density functional approximations. Using an optimized hybrid functional, we then reveal a low-symmetry structure for phase II generated by an out-of-plane librational instability of the C2/c phase III structure. This instability weakens the in-plane polarization of C2/c leading to the well-known experimental signatures of the II-III phase transition such as a sharp shift in vibron frequency, infrared activity and $c/a$ lattice parameter ratio. Finally, we discuss the zero-point vibrational energy that plays an important role in stabilizing phase III at lower pressures.
format Preprint
id arxiv_https___arxiv_org_abs_2205_01368
institution arXiv
publishDate 2022
record_format arxiv
spellingShingle High-pressure II-III phase transition in solid hydrogen: Insights from state-of-the-art ab initio calculations
Hellgren, Maria
Contant, Damian
Pitts, Thomas
Casula, Michele
Materials Science
The high-pressure II-III phase transition in solid hydrogen is investigated using the random phase approximation and diffusion Monte Carlo. Good agreement between the methods is found confirming that an accurate treatment of exchange and correlation increases the transition pressure by more than 100 GPa with respect to semilocal density functional approximations. Using an optimized hybrid functional, we then reveal a low-symmetry structure for phase II generated by an out-of-plane librational instability of the C2/c phase III structure. This instability weakens the in-plane polarization of C2/c leading to the well-known experimental signatures of the II-III phase transition such as a sharp shift in vibron frequency, infrared activity and $c/a$ lattice parameter ratio. Finally, we discuss the zero-point vibrational energy that plays an important role in stabilizing phase III at lower pressures.
title High-pressure II-III phase transition in solid hydrogen: Insights from state-of-the-art ab initio calculations
topic Materials Science
url https://arxiv.org/abs/2205.01368