arxiv_ai 90% Match Research Paper Computational Chemists,Physicists,Materials Scientists,ML Researchers in Scientific Computing 2 weeks ago

High-order Equivariant Flow Matching for Density Functional Theory Hamiltonian Prediction

graph-neural-networks › molecular-modeling

📄 Abstract

Abstract: Density functional theory (DFT) is a fundamental method for simulating quantum chemical properties, but it remains expensive due to the iterative self-consistent field (SCF) process required to solve the Kohn-Sham equations. Recently, deep learning methods are gaining attention as a way to bypass this step by directly predicting the Hamiltonian. However, they rely on deterministic regression and do not consider the highly structured nature of Hamiltonians. In this work, we propose QHFlow, a high-order equivariant flow matching framework that generates Hamiltonian matrices conditioned on molecular geometry. Flow matching models continuous-time trajectories between simple priors and complex targets, learning the structured distributions over Hamiltonians instead of direct regression. To further incorporate symmetry, we use a neural architecture that predicts SE(3)-equivariant vector fields, improving accuracy and generalization across diverse geometries. To further enhance physical fidelity, we additionally introduce a fine-tuning scheme to align predicted orbital energies with the target. QHFlow achieves state-of-the-art performance, reducing Hamiltonian error by 71% on MD17 and 53% on QH9. Moreover, we further show that QHFlow accelerates the DFT process without trading off the solution quality when initializing SCF iterations with the predicted Hamiltonian, significantly reducing the number of iterations and runtime.

Authors (4)

Seongsu Kim

Nayoung Kim

Dongwoo Kim

Sungsoo Ahn

Submitted

May 24, 2025

arXiv Category

physics.comp-ph

arXiv PDF

Key Contributions

Proposes QHFlow, a high-order equivariant flow matching framework for predicting Hamiltonian matrices conditioned on molecular geometry, bypassing the expensive SCF process in DFT. It learns structured distributions over Hamiltonians and uses SE(3)-equivariant networks to incorporate symmetry.

Business Value

Accelerates scientific discovery in fields like drug design, materials science, and catalysis by enabling faster and more accurate quantum chemical simulations. Reduces the cost of computational research.

Paper Metadata

Innovation Type

Algorithmic

Deployment Feasibility

Moderate. Requires expertise in quantum chemistry and deep learning. Integration into existing DFT workflows is a challenge.

Limitations Addressed

The computational expense of the iterative self-consistent field (SCF) process in Density Functional Theory (DFT) and the limitations of deterministic regression methods for Hamiltonian prediction.

Performance Gains

Aims to significantly reduce the computational cost of DFT calculations while maintaining or improving accuracy.

Technical Tags

equivariant flow matchingdensity functional theory (DFT)Hamiltonian predictionquantum chemistryKohn-Sham equationsflow matchingSE(3)-equivariantmolecular geometrysymmetryneural networks

Research Topics

Quantum ChemistryComputational PhysicsMachine Learning for ScienceGenerative ModelsGeometric Deep Learning

Methods & Architectures

Equivariant Flow MatchingSE(3)-Equivariant Neural NetworksHamiltonian PredictionDeep Generative Models Equivariant Neural NetworkFlow Matching Model

Applications & Tasks

Quantum Chemistry Materials Science Drug Discovery Computational Physics Accelerating DFT calculationsPredicting molecular propertiesLearning structured distributions Hamiltonian matrix predictionQuantum mechanical simulationsMolecular property prediction

Related Fields

ChemistryPhysicsMaterials ScienceMachine LearningComputer Science

Keywords

density functional theoryDFTHamiltonian predictionequivariant neural networksflow matchingquantum chemistrymolecular modelingSE(3) equivariancesymmetrygenerative modelsmaterials sciencedrug discovery

Academic Context

#Quantum Chemistry#Computational Physics#Machine Learning for Science#Generative Models#Geometric Deep Learning

Commercial Potential

Potential Products

Accelerated DFT simulation softwarePredictive models for molecular propertiesDrug discovery platforms

Target Industries

PharmaceuticalsMaterials ScienceChemicalsSemiconductorsEnergy

Use Case Examples

Screening potential drug candidatesDesigning novel materials with specific propertiesSimulating chemical reactions

Competitive Edge

Offers a novel generative approach (equivariant flow matching) for Hamiltonian prediction, leveraging physical symmetries, which may outperform direct regression or non-equivariant methods.

Market Opportunity

The market for computational chemistry and materials simulation software is significant.

Revenue Models

Licensing of softwarecloud-based simulation servicesspecialized prediction models.

Resource Requirements

Compute Needs

High, especially for training SE(3)-equivariant models and flow matching on large molecular datasets.

Data Requirements

Large datasets of molecular structures and corresponding Hamiltonians or DFT calculation results.

Deployment Constraints

Requires accurate molecular geometry inputs,Computational cost for inference,Integration with quantum chemistry simulation software

Scalability

Equivariant models can scale well with system size, but training complexity remains high.

Production Readiness

Maturity Level

Research

Time to Market

3-7 years for widespread adoption in research labs and industry.

Patent Potential

High, for the novel QHFlow framework and its equivariant architecture.

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