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Evolving symbolic density functionals.

He Ma1, Arunachalam Narayanaswamy1, Patrick Riley1,2

  • 1Google Research, Mountain View, CA 94043, USA.

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Summary
This summary is machine-generated.

Scientists developed Symbolic Functional Evolutionary Search (SyFES) to automatically create accurate, human-readable symbolic density functionals. This machine learning approach offers a more explainable and efficient alternative to complex, parameter-heavy models.

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Area of Science:

  • Computational Chemistry
  • Materials Science
  • Quantum Mechanics

Background:

  • Developing accurate density functionals is a long-standing challenge in computational science.
  • Existing machine learning (ML) functionals often have too many parameters, hindering interpretability and integration.
  • A gap exists between complex ML functionals and traditional human-designed symbolic functionals.

Purpose of the Study:

  • To introduce a novel framework, Symbolic Functional Evolutionary Search (SyFES), for automated symbolic functional development.
  • To create density functionals that are explainable, computationally cheaper, and easier to integrate into existing software.
  • To advance the systematic development of symbolic density functionals using computational power.

Main Methods:

  • SyFES automatically constructs functionals in a symbolic form.
  • The framework was tested by reconstructing a known functional without prior knowledge.
  • SyFES evolved an existing functional (ωB97M-V) to discover new, improved functionals.

Main Results:

  • SyFES successfully reconstructed a known functional from scratch, demonstrating its capability.
  • A new functional, GAS22 (Google Accelerated Science 22), was discovered by evolving ωB97M-V.
  • GAS22 exhibited superior performance across most molecular types in the MGCDB84 dataset.

Conclusions:

  • SyFES provides an effective method for the automated, systematic development of symbolic density functionals.
  • The SyFES framework bridges the gap between complex ML models and interpretable symbolic functionals.
  • This approach opens new avenues for leveraging computational resources in functional development.