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Efficient implementation of atom-density representations.

Félix Musil1, Max Veit1, Alexander Goscinski1

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|March 23, 2021
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Summary
This summary is machine-generated.

Atomistic machine learning relies on robust molecular representations. A new implementation, librascal, optimizes these representations, reducing computational cost by up to four times without sacrificing accuracy or symmetry properties.

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Area of Science:

  • Computational chemistry
  • Materials informatics
  • Machine learning

Background:

  • Atom-centered representations are crucial for atomistic machine learning, enabling property prediction and structure visualization.
  • Many effective representations share a formal connection as discretizations of n-body correlation functions of local atom density.
  • Optimizing the evaluation of these representations offers significant potential for computational efficiency.

Purpose of the Study:

  • To present librascal, a modular implementation for developing and optimizing atomistic representations.
  • To demonstrate the optimization of smooth overlap of atomic position (SOAP) features using librascal.
  • To analyze the computational scaling and explore data reduction techniques for these representations.

Main Methods:

  • Development of the modular librascal implementation for atomistic representations.
  • Optimization of local atom density expansions for smooth overlap of atomic position (SOAP) features.
  • Application of kernel ridge regression and data reduction techniques in feature space.

Main Results:

  • The librascal implementation facilitates refinement and rapid prototyping of rotationally equivariant atomistic representations.
  • Optimization of SOAP feature expansion was demonstrated for various radial basis sets.
  • Data reduction techniques reduced total computational cost by up to 4x without significant accuracy loss or impact on symmetry properties.

Conclusions:

  • The density-based formalism provides a unifying framework for atomistic representations.
  • Librascal enables efficient optimization and development of these representations.
  • Computational cost reduction is achievable through feature space optimization and data reduction, enhancing the applicability of atomistic machine learning.