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HyperDiffusionFields (HyDiF): Diffusion-Guided Hypernetworks for Learning Implicit Molecular Neural Fields

generative-ai › diffusion

📄 Abstract

Abstract: We introduce HyperDiffusionFields (HyDiF), a framework that models 3D molecular conformers as continuous fields rather than discrete atomic coordinates or graphs. At the core of our approach is the Molecular Directional Field (MDF), a vector field that maps any point in space to the direction of the nearest atom of a particular type. We represent MDFs using molecule-specific neural implicit fields, which we call Molecular Neural Fields (MNFs). To enable learning across molecules and facilitate generalization, we adopt an approach where a shared hypernetwork, conditioned on a molecule, generates the weights of the given molecule's MNF. To endow the model with generative capabilities, we train the hypernetwork as a denoising diffusion model, enabling sampling in the function space of molecular fields. Our design naturally extends to a masked diffusion mechanism to support structure-conditioned generation tasks, such as molecular inpainting, by selectively noising regions of the field. Beyond generation, the localized and continuous nature of MDFs enables spatially fine-grained feature extraction for molecular property prediction, something not easily achievable with graph or point cloud based methods. Furthermore, we demonstrate that our approach scales to larger biomolecules, illustrating a promising direction for field-based molecular modeling.

Authors (8)

Sudarshan Babu

Phillip Lo

Xiao Zhang

Aadi Srivastava

Ali Davariashtiyani

Jason Perera

+2 more

Submitted

October 20, 2025

arXiv Category

cs.LG

arXiv PDF

Key Contributions

Introduces HyperDiffusionFields (HyDiF), a framework that models 3D molecular conformers using diffusion-guided hypernetworks generating implicit molecular neural fields (MNFs). It learns a Molecular Directional Field (MDF) and enables generative capabilities through diffusion in function space, supporting tasks like molecular inpainting.

Business Value

Accelerates drug discovery and materials science by enabling the generation of novel molecular structures with desired properties, potentially reducing R&D costs and time.

Paper Metadata

Innovation Type

Novel Framework/Architecture

Deployment Feasibility

Moderate, requires significant computational resources for training and inference, and specialized domain expertise.

Limitations Addressed

Addresses the challenge of modeling 3D molecular conformers as continuous fields and enables generalization across molecules by using hypernetworks, while leveraging diffusion models for generative power.

Technical Tags

molecular conformationimplicit neural fieldshypernetworksdiffusion modelsdenoising diffusionmolecular directional field (MDF)function space samplingmasked diffusionstructure-conditioned generationmolecular inpainting

Research Topics

Molecular ModelingGenerative AIDeep Learning for ChemistryImplicit RepresentationsDiffusion Models

Methods & Architectures

HypernetworksDenoising Diffusion ModelsMasked DiffusionImplicit Neural FieldsMolecular Directional Field (MDF) HypernetworkImplicit Neural FieldDenoising Diffusion Model

Applications & Tasks

Drug Discovery Materials Science Computational Chemistry Molecular Design Generating 3D Molecular ConformationsLearning Implicit Molecular RepresentationsStructure-Conditioned GenerationMolecular Inpainting Conformer GenerationMolecular Property Prediction (indirectly)De Novo Molecular Design

Related Fields

Computational ChemistryDrug DiscoveryGenerative ModelsMachine Learning for Science3D Deep Learning

Keywords

Molecular ConformationImplicit Neural FieldsHypernetworksDiffusion ModelsGenerative AIDrug DiscoveryComputational ChemistryMolecular Design3D GenerationMDFMNF

Academic Context

#Molecular Modeling#Generative AI#Deep Learning for Chemistry#Implicit Representations#Diffusion Models

Technology Stack

ML Infrastructure

GPU clusters

Commercial Potential

Potential Products

Molecular design platformsDrug candidate generation toolsMaterials discovery software

Target Industries

PharmaceuticalsBiotechnologyMaterials ScienceChemicals

Use Case Examples

Generating novel drug candidatesDesigning new materials with specific propertiesPredicting molecular properties through generative modeling

Competitive Edge

Offers a novel approach combining hypernetworks and diffusion models for molecular field generation, potentially outperforming existing methods in generalization and generative quality.

Market Opportunity

Large and growing market for AI in drug discovery and materials science.

Revenue Models

SaaS for molecular design platformslicensing of generative models.

Resource Requirements

Compute Needs

High (for training diffusion models and hypernetworks)

Data Requirements

Large datasets of molecular structures and properties

Deployment Constraints

Computational cost, need for specialized molecular data.

Scalability

Scalability depends on the efficiency of hypernetwork and diffusion model training.

Regulatory Considerations

Data privacy for proprietary molecular datasets.

Production Readiness

Maturity Level

Research

Time to Market

2-4 years for integration into R&D pipelines

Patent Potential

Potential for patents on novel molecular generation methods.

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