High temperature melting of dense molecular hydrogen from machine-learning interatomic potentials trained on quantum Monte Carlo

Shubhang Goswami; Scott Jensen; Yubo Yang; Markus Holzmann; Carlo Pierleoni; David M. Ceperley

doi:10.1063/5.0250686

High temperature melting of dense molecular hydrogen from machine-learning interatomic potentials trained on quantum Monte Carlo

Shubhang Goswami, Scott Jensen, Yubo Yang, Markus Holzmann, Carlo Pierleoni, David M. Ceperley

Research output: Contribution to journal › Article › peer-review

Abstract

We present results and discuss methods for computing the melting temperature of dense molecular hydrogen using a machine learned model trained on quantum Monte Carlo data. In this newly trained model, we emphasize the importance of accurate total energies in the training. We integrate a two phase method for estimating the melting temperature with estimates from the Clausius-Clapeyron relation to provide a more accurate melting curve from the model. We make detailed predictions of the melting temperature, solid and liquid volumes, latent heat, and internal energy from 50 to 180 GPa for both classical hydrogen and quantum hydrogen. At pressures of roughly 173 GPa and 1635 K, we observe molecular dissociation in the liquid phase. We compare with previous simulations and experimental measurements.

Original language	English (US)
Article number	054118
Journal	Journal of Chemical Physics
Volume	162
Issue number	5
Early online date	Feb 5 2025
DOIs	https://doi.org/10.1063/5.0250686
State	Published - Feb 7 2025

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General Physics and Astronomy
Physical and Theoretical Chemistry

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10.1063/5.0250686

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title = "High temperature melting of dense molecular hydrogen from machine-learning interatomic potentials trained on quantum Monte Carlo",

abstract = "We present results and discuss methods for computing the melting temperature of dense molecular hydrogen using a machine learned model trained on quantum Monte Carlo data. In this newly trained model, we emphasize the importance of accurate total energies in the training. We integrate a two phase method for estimating the melting temperature with estimates from the Clausius-Clapeyron relation to provide a more accurate melting curve from the model. We make detailed predictions of the melting temperature, solid and liquid volumes, latent heat, and internal energy from 50 to 180 GPa for both classical hydrogen and quantum hydrogen. At pressures of roughly 173 GPa and 1635 K, we observe molecular dissociation in the liquid phase. We compare with previous simulations and experimental measurements.",

author = "Shubhang Goswami and Scott Jensen and Yubo Yang and Markus Holzmann and Carlo Pierleoni and Ceperley, {David M.}",

note = "The Flatiron Institute is a division of the Simons Foundation. Work by S.G., D.M.C., and S.J. was supported by the U.S. Department of Energy (DOE), Office of Science, Basic Energy Sciences (BES) under Award No. DE-SC0020177. C.P. was supported by the European Union\u2014NextGenerationEU under the Italian Ministry of University and Research (MUR) Project Nos. PRIN2022-2022NRBLPT, CUP E53D23001790006, PRIN2022-P2022MC742PNRR, and CUP E53D23018440001. We thank the QMC-HAMM team and Niu for their valuable discussions. Comparison of melting lines from various calculations was performed on the Illinois Campus Cluster and Delta, supported by the National Science Foundation (Award Nos. OCI-0725070 and ACI-1238993), the state of Illinois, the University of Illinois at Urbana-Champaign, and its National Center for Supercomputing Applications.",

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AU - Ceperley, David M.

N1 - The Flatiron Institute is a division of the Simons Foundation. Work by S.G., D.M.C., and S.J. was supported by the U.S. Department of Energy (DOE), Office of Science, Basic Energy Sciences (BES) under Award No. DE-SC0020177. C.P. was supported by the European Union\u2014NextGenerationEU under the Italian Ministry of University and Research (MUR) Project Nos. PRIN2022-2022NRBLPT, CUP E53D23001790006, PRIN2022-P2022MC742PNRR, and CUP E53D23018440001. We thank the QMC-HAMM team and Niu for their valuable discussions. Comparison of melting lines from various calculations was performed on the Illinois Campus Cluster and Delta, supported by the National Science Foundation (Award Nos. OCI-0725070 and ACI-1238993), the state of Illinois, the University of Illinois at Urbana-Champaign, and its National Center for Supercomputing Applications.

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N2 - We present results and discuss methods for computing the melting temperature of dense molecular hydrogen using a machine learned model trained on quantum Monte Carlo data. In this newly trained model, we emphasize the importance of accurate total energies in the training. We integrate a two phase method for estimating the melting temperature with estimates from the Clausius-Clapeyron relation to provide a more accurate melting curve from the model. We make detailed predictions of the melting temperature, solid and liquid volumes, latent heat, and internal energy from 50 to 180 GPa for both classical hydrogen and quantum hydrogen. At pressures of roughly 173 GPa and 1635 K, we observe molecular dissociation in the liquid phase. We compare with previous simulations and experimental measurements.

AB - We present results and discuss methods for computing the melting temperature of dense molecular hydrogen using a machine learned model trained on quantum Monte Carlo data. In this newly trained model, we emphasize the importance of accurate total energies in the training. We integrate a two phase method for estimating the melting temperature with estimates from the Clausius-Clapeyron relation to provide a more accurate melting curve from the model. We make detailed predictions of the melting temperature, solid and liquid volumes, latent heat, and internal energy from 50 to 180 GPa for both classical hydrogen and quantum hydrogen. At pressures of roughly 173 GPa and 1635 K, we observe molecular dissociation in the liquid phase. We compare with previous simulations and experimental measurements.

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High temperature melting of dense molecular hydrogen from machine-learning interatomic potentials trained on quantum Monte Carlo

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