Prediction of a Mobile Solid State in Dense Hydrogen under High Pressures

Geng, Hua-Yun; Wu, Qiang; Sun, Yi

doi:10.1021/acs.jpclett.6b02453

Cited by 15 publications

(7 citation statements)

References 34 publications

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“…The latter two phases have alternating layers of rotating molecules similar to Phase I, and weak molecules akin to Phase III [1] [13][14] [15]. Other phases under extreme compression include the recent claimed (and still controversial) molecular conductor or atomic metal [12][22] [23], the predicted mobile solid state [2] [21], and superconducting superfluid quantum liquid [24][25] [26]. This wide range of behavior highlights the significance of dense hydrogen as an archetype of a manybody quantum system [23][24] [27].…”

Section: Introductionmentioning

confidence: 99%

“…Rich physics and chemistry have been discovered, and are still being predicted in both pure hydrogen [1] [2][3] and hydrogen-rich compounds [4] [5][6] [7]. Dense solid hydrogen shows an unexpectedly complicated phase diagram [8][9][10] [11][12] [13][14] [15] with an anomalous melting curve maximum and minimum [3][16][17] [18][19] [20][21], embodying solid states based around free rotating molecules (Phase I), broken symmetry due to quadrupole interactions (Phase II), packing of weakly bonded molecules (Phase III), and proposed "mixed" state (phases IV and V).…”

Section: Introductionmentioning

confidence: 99%

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Thermodynamic anomalies and three distinct liquid-liquid transitions in warm dense liquid hydrogen

Geng

Wu²,

Marqués

et al. 2019

Phys. Rev. B

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The properties of hydrogen at high pressure have wide implications in astrophysics and high-pressure physics. Its phase change in the liquid is variously described as a metallization, H2-dissociation, density discontinuity or plasma phase transition. It has been tacitly assumed that these phenomena coincide at a first-order liquid-liquid transition (LLT). In this work, the relevant pressure-temperature conditions are thoroughly explored with first-principles molecular dynamics. We show there is a large dependency on exchange-correlation functional and significant finite size effects. We use hysteresis in a number of measurable quantities to demonstrate a first-order transition up to a critical point, above which molecular and atomic liquids are indistinguishable. At higher temperature beyond the critical point, H2-dissociation becomes a smooth cross-over in the supercritical region that can be modelled by a pseudo-transition, where the H2→2H transformation is localized and does not cause a density discontinuity at metallization. Thermodynamic anomalies and counter-intuitive transport behavior of protons are also discovered even far beyond the critical point, making this dissociative transition highly relevant to the Supplementary Material. Results of dimer-dimer bond-length distribution (DDLD) calculations, comparison between PBE and vdW-DF results, the thermodynamic modelling of pseudo-transition and phase boundaries, calculated isotherms (equation of state, EOS), transient clusters and their lifetime and charge state, the angular distribution function of H3 clusters, mixing of H and H2 liquid, thermal fluctuation analysis, isotope effect, finite size effects, and the assessment of proton selfdiffusivity and viscosity.

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Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Thermodynamic anomalies and three distinct liquid-liquid transitions in warm dense liquid hydrogen

Geng

Wu²,

Marqués

et al. 2019

Phys. Rev. B

Self Cite

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“…2 Therefore, much effort has been directed toward searching for candidate structures of solid hydrogen by combining DFT with optimization algorithms at high pressures and low temperatures, which has improved our understanding of the experimental observations [18][19][20][21][22] and predicted some peculiar properties for hydrogen at pressures beyond those explored experimentally. [23][24][25][26] The C2/c structure was proposed for phase III above 200 GPa and its Raman and IR vibrons exhibit good agreement with the experimental observations. Compared with phase III, the experimental Raman (infrared) spectrum of phase IV is more complex, and has two distinct vibron frequencies.…”

Section: Introductionmentioning

confidence: 53%

New possible candidate structure for phase IV of solid hydrogen

et al. 2020

RSC Adv.

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“…Palmer called such a region the "component" [3], and we note that conventional equilibrium statistics are exactly designed to handle such intracomponent motions. However, the temporal DOF becomes nontrivial when T is moderate: there are rare but significant inter-component motions for particles moving farther away beyond thermal fluctuations [18][19][20], which contributes to transport properties such as the diffusion coefficients and ionic mobility [21]. Instead of treating those motions as typical nonequilibrium phenomena, we found the dynamics for inter-component motions gradually become homogeneous towards the long time limit [17].…”

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confidence: 76%

Dynamic phase transition theory

Ye¹,

Li²

2022

Preprint

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Thermodynamic conventions suffer from describing systems in motion, especially when the structural and energetic changes induced by localized rare events are insignificant. By using the ensemble theory in the trajectory space, we present a statistical approach to address this problem. Rather than spatial particle-particle interaction which dominates thermodynamics, the temporal correlation of events dominates the dynamics. The zeros of dynamic partition function mark phase transitions in the space-time, i.e. dynamic phase transition (DPT), as Yang and Lee formulate traditional phase transitions, and hence determine dynamic phases on both sides of the zeros. Analogous to the role of temperature (pressure) as thermal (mechanical) potential, we interpret the controlling variable of DPT, i.e. dynamic field, as the dynamical potential. These findings offer possibility towards a unified picture of phase and phase transition.

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Prediction of a Mobile Solid State in Dense Hydrogen under High Pressures

Cited by 15 publications

References 34 publications

Thermodynamic anomalies and three distinct liquid-liquid transitions in warm dense liquid hydrogen

Thermodynamic anomalies and three distinct liquid-liquid transitions in warm dense liquid hydrogen

New possible candidate structure for phase IV of solid hydrogen

Dynamic phase transition theory

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