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Machine learning the metastable phase diagram of covalently bonded carbon

Author

Listed:
  • Srilok Srinivasan

    (Argonne National Laboratory)

  • Rohit Batra

    (Argonne National Laboratory)

  • Duan Luo

    (Argonne National Laboratory)

  • Troy Loeffler

    (Argonne National Laboratory)

  • Sukriti Manna

    (Argonne National Laboratory
    University of Illinois)

  • Henry Chan

    (Argonne National Laboratory
    University of Illinois)

  • Liuxiang Yang

    (Center for High Pressure Science and Technology Advanced Research)

  • Wenge Yang

    (Center for High Pressure Science and Technology Advanced Research)

  • Jianguo Wen

    (Argonne National Laboratory)

  • Pierre Darancet

    (Argonne National Laboratory
    Northwestern Argonne Institute of Science and Engineering)

  • Subramanian K.R.S. Sankaranarayanan

    (Argonne National Laboratory
    University of Illinois)

Abstract

Conventional phase diagram generation involves experimentation to provide an initial estimate of the set of thermodynamically accessible phases and their boundaries, followed by use of phenomenological models to interpolate between the available experimental data points and extrapolate to experimentally inaccessible regions. Such an approach, combined with high throughput first-principles calculations and data-mining techniques, has led to exhaustive thermodynamic databases (e.g. compatible with the CALPHAD method), albeit focused on the reduced set of phases observed at distinct thermodynamic equilibria. In contrast, materials during their synthesis, operation, or processing, may not reach their thermodynamic equilibrium state but, instead, remain trapped in a local (metastable) free energy minimum, which may exhibit desirable properties. Here, we introduce an automated workflow that integrates first-principles physics and atomistic simulations with machine learning (ML), and high-performance computing to allow rapid exploration of the metastable phases to construct “metastable” phase diagrams for materials far-from-equilibrium. Using carbon as a prototypical system, we demonstrate automated metastable phase diagram construction to map hundreds of metastable states ranging from near equilibrium to far-from-equilibrium (400 meV/atom). We incorporate the free energy calculations into a neural-network-based learning of the equations of state that allows for efficient construction of metastable phase diagrams. We use the metastable phase diagram and identify domains of relative stability and synthesizability of metastable materials. High temperature high pressure experiments using a diamond anvil cell on graphite sample coupled with high-resolution transmission electron microscopy (HRTEM) confirm our metastable phase predictions. In particular, we identify the previously ambiguous structure of n-diamond as a cubic-analog of diaphite-like lonsdaelite phase.

Suggested Citation

  • Srilok Srinivasan & Rohit Batra & Duan Luo & Troy Loeffler & Sukriti Manna & Henry Chan & Liuxiang Yang & Wenge Yang & Jianguo Wen & Pierre Darancet & Subramanian K.R.S. Sankaranarayanan, 2022. "Machine learning the metastable phase diagram of covalently bonded carbon," Nature Communications, Nature, vol. 13(1), pages 1-12, December.
    • Handle: RePEc:nat:natcom:v:13:y:2022:i:1:d:10.1038_s41467-022-30820-8
    DOI: 10.1038/s41467-022-30820-8
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    References listed on IDEAS

    as
    1. Sukriti Manna & Troy D. Loeffler & Rohit Batra & Suvo Banik & Henry Chan & Bilvin Varughese & Kiran Sasikumar & Michael Sternberg & Tom Peterka & Mathew J. Cherukara & Stephen K. Gray & Bobby G. Sumpt, 2022. "Learning in continuous action space for developing high dimensional potential energy models," Nature Communications, Nature, vol. 13(1), pages 1-10, December.
    2. Bundy, F.P., 1989. "Pressure-temperature phase diagram of elemental carbon," Physica A: Statistical Mechanics and its Applications, Elsevier, vol. 156(1), pages 169-178.
    3. Daniel J. Rizzo & Gregory Veber & Ting Cao & Christopher Bronner & Ting Chen & Fangzhou Zhao & Henry Rodriguez & Steven G. Louie & Michael F. Crommie & Felix R. Fischer, 2018. "Topological band engineering of graphene nanoribbons," Nature, Nature, vol. 560(7717), pages 204-208, August.
    4. F. Zipoli & M. Bernasconi & R. Martoňák, 2004. "Constant pressure reactive molecular dynamics simulations of phase transitions under pressure: The graphite to diamond conversion revisited," The European Physical Journal B: Condensed Matter and Complex Systems, Springer;EDP Sciences, vol. 39(1), pages 41-47, May.
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