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Genarris 3.0: Generating Close-Packed Molecular Crystal Structures with Rigid Press.

Yi Yang1, Rithwik Tom2, Jose A G L Wui3

  • 1Department of Materials Science & Engineering, Carnegie Mellon University, Pittsburgh, Pennsylvania 15213, United States.

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Genarris 3.0 enhances crystal structure prediction by introducing a "Rigid Press" algorithm and machine-learned potentials for faster exploration. This open-source tool aids in discovering new polymorphs and generating data for machine learning models.

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Area of Science:

  • Crystallography
  • Computational Chemistry
  • Materials Science

Background:

  • Molecular crystal polymorphism significantly impacts material properties and performance.
  • Crystal structure prediction (CSP) is crucial for computationally exploring polymorphs.
  • Existing methods require significant computational resources for exploring the crystal structure landscape.

Purpose of the Study:

  • To introduce Genarris 3.0, an enhanced open-source code for molecular crystal structure prediction.
  • To accelerate the exploration of potential energy landscapes using machine-learned interatomic potentials (MLIPs).
  • To develop and validate a new clustering and down-selection workflow for efficient polymorph ranking.

Main Methods:

  • Genarris 3.0 incorporates a novel "Rigid Press" algorithm for geometric compression.
  • Integration with MACE-OFF23(L) MLIPs for accelerated geometry optimization and energy ranking.
  • Application of a clustering and down-selection workflow for efficient data processing.

Main Results:

  • Genarris 3.0 successfully predicted crystal structures for six diverse targets, including energetic materials.
  • Analysis revealed variability in MLIP performance, particularly for energetic materials, which was mitigated by the new workflow.
  • The code effectively generates molecular crystal data sets suitable for training machine learning models.

Conclusions:

  • Genarris 3.0 offers an efficient and effective platform for crystal structure prediction.
  • The integration of MLIPs and a robust workflow accelerates the discovery of stable polymorphs.
  • The generated data sets are valuable for advancing machine learning applications in materials science.