arxiv_ml 85% Match Research Paper Computational chemists,Molecular modelers,Researchers in generative AI for science 3 weeks ago

Enhancing Diffusion-Based Sampling with Molecular Collective Variables

generative-ai › diffusion

📄 Abstract

Abstract: Diffusion-based samplers learn to sample complex, high-dimensional distributions using energies or log densities alone, without training data. Yet, they remain impractical for molecular sampling because they are often slower than molecular dynamics and miss thermodynamically relevant modes. Inspired by enhanced sampling, we encourage exploration by introducing a sequential bias along bespoke, information-rich, low-dimensional projections of atomic coordinates known as collective variables (CVs). We introduce a repulsive potential centered on the CVs from recent samples, which pushes future samples towards novel CV regions and effectively increases the temperature in the projected space. Our resulting method improves efficiency, mode discovery, enables the estimation of free energy differences, and retains independent sampling from the approximate Boltzmann distribution via reweighting by the bias. On standard peptide conformational sampling benchmarks, the method recovers diverse conformational states and accurate free energy profiles. We are the first to demonstrate reactive sampling using a diffusion-based sampler, capturing bond breaking and formation with universal interatomic potentials at near-first-principles accuracy. The approach resolves reactive energy landscapes at a fraction of the wall-clock time of standard sampling methods, advancing diffusion-based sampling towards practical use in molecular sciences.

Authors (9)

Juno Nam

Bálint Máté

Artur P. Toshev

Manasa Kaniselvan

Rafael Gómez-Bombarelli

Ricky T. Q. Chen

+3 more

Submitted

October 13, 2025

arXiv Category

physics.chem-ph

arXiv PDF

Key Contributions

Enhances diffusion-based samplers for molecular applications by introducing a sequential bias along low-dimensional collective variables (CVs). This bias potential encourages exploration of novel CV regions, improving sampling efficiency, mode discovery, and enabling free energy difference estimation while retaining the ability to reweight for the true Boltzmann distribution.

Business Value

Accelerates molecular simulations, leading to faster discovery of new drugs, materials, and understanding of chemical processes.

Paper Metadata

Innovation Type

Algorithmic Enhancement

Deployment Feasibility

Requires expertise in molecular dynamics and computational chemistry to define appropriate collective variables. The method itself is an algorithmic enhancement to existing samplers.

Limitations Addressed

Diffusion samplers are often too slow for molecular simulations compared to molecular dynamics and can miss important thermodynamic modes. This method addresses these limitations by guiding the sampling process using domain-specific knowledge (CVs).

Performance Gains

Improves efficiency, mode discovery, and enables free energy estimation compared to standard diffusion samplers.

Technical Tags

diffusion modelsmolecular samplingcollective variablesenhanced samplingbias potentialfree energy estimationconformational samplingreweightinglow-dimensional projection

Research Topics

Generative ModelingMolecular DynamicsComputational ChemistryEnhanced Sampling TechniquesDimensionality Reduction

Methods & Architectures

Diffusion-based SamplingMolecular Collective Variables (CVs)Bias PotentialSequential SamplingReweighting Diffusion Models

Applications & Tasks

Computational Chemistry Molecular Dynamics Simulations Drug Discovery Materials Science Efficient Molecular SamplingExploring Complex Energy LandscapesEstimating Free Energy Differences Accelerating Molecular SamplingImproving Mode DiscoveryEstimating Free EnergyConformational Analysis

Datasets & Benchmarks

Datasets

peptide conformational sampling benchmarks

Benchmarks

peptide conformational sampling benchmarks

EfficiencyMode discoveryFree energy estimation accuracySampling speed

Related Fields

Statistical MechanicsComputational PhysicsMachine LearningGenerative ModelsChemistry

Keywords

diffusion modelsmolecular dynamicscollective variablesenhanced samplingfree energy calculationconformational samplinggenerative modelsbias potentialreweightinglow-dimensional projectioncomputational chemistrysampling efficiency

Academic Context

#Generative Modeling#Molecular Dynamics#Computational Chemistry#Enhanced Sampling Techniques#Dimensionality Reduction

Commercial Potential

Potential Products

Accelerated molecular simulation softwareTools for drug discovery and materials design

Target Industries

PharmaceuticalsBiotechnologyMaterials ScienceChemical Industry

Use Case Examples

Simulating protein folding dynamicsDesigning new catalystsPredicting material properties

Competitive Edge

Offers a more efficient and effective approach to molecular sampling compared to standard diffusion models or traditional molecular dynamics methods for exploring complex energy landscapes.

Market Opportunity

Significant market in computational chemistry and drug discovery tools.

Resource Requirements

Compute Needs

High, typical for molecular dynamics simulations.

Data Requirements

Requires molecular structures and associated energy potentials.

Deployment Constraints

Requires specialized knowledge of molecular modeling and the definition of effective collective variables.

Scalability

The method aims to improve efficiency, but scaling to extremely large molecular systems remains a challenge.

Production Readiness

Maturity Level

Research/Applied

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