2017
DOI: 10.1103/physrevlett.118.015703
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Acceleratingab initioMolecular Dynamics and Probing the Weak Dispersive Forces in Dense Liquid Hydrogen

Abstract: We propose an ab-initio molecular dynamics method, capable to reduce dramatically the autocorrelation time required for the simulation of classical and quantum particles at finite temperature. The method is based on an efficient implementation of a first order Langevin dynamics modified by means of a suitable, position dependent acceleration matrix S. Here we apply this technique, within a Quantum Monte Carlo (QMC) based wavefunction approach and within the Born-Oppheneimer approximation, for determining the p… Show more

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Cited by 29 publications
(28 citation statements)
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“…However, the few QMC results for the H phase diagram, until now, have not agreed well. In particular, while all QMC simulations agreed qualitatively on a larger dissociation and metallization pressure for pure dense liquid H, compared to PBE, the precise location was not welldetermined due to different QMC implementations, variational wave-function, and finite size effects errors 9,[20][21][22][23] . We perform simulations with 64 and 128 H atoms for the H compound and with 118 H and 10 He atoms for the H-He mixture (see Methods).…”
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confidence: 97%
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“…However, the few QMC results for the H phase diagram, until now, have not agreed well. In particular, while all QMC simulations agreed qualitatively on a larger dissociation and metallization pressure for pure dense liquid H, compared to PBE, the precise location was not welldetermined due to different QMC implementations, variational wave-function, and finite size effects errors 9,[20][21][22][23] . We perform simulations with 64 and 128 H atoms for the H compound and with 118 H and 10 He atoms for the H-He mixture (see Methods).…”
mentioning
confidence: 97%
“…We plot g(r) at different particle densities (defined using the Wigner-Seitz radius defined above) at each temperature in order to constrain the metallization/dissociation crossover. The single Z basis refers to the one adopted in the previous work 23 , where the accelerated molecular dynamics was introduced. 2Z and 3Z basis sets refer instead to the more conventional "correlation consistent polarized valence x−zeta" (ccpVxZ , with x = 2, 3, respectively) sequence 40 .…”
Section: Additional Figuresmentioning
confidence: 99%
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