arxiv_ai 95% Match Research Paper Crystallographers,Materials scientists,Chemists,Drug discovery researchers,Deep learning researchers 2 weeks ago

XDXD: End-to-end crystal structure determination with low resolution X-ray diffraction

generative-ai › diffusion

📄 Abstract

Abstract: Determining crystal structures from X-ray diffraction data is fundamental across diverse scientific fields, yet remains a significant challenge when data is limited to low resolution. While recent deep learning models have made breakthroughs in solving the crystallographic phase problem, the resulting low-resolution electron density maps are often ambiguous and difficult to interpret. To overcome this critical bottleneck, we introduce XDXD, to our knowledge, the first end-to-end deep learning framework to determine a complete atomic model directly from low-resolution single-crystal X-ray diffraction data. Our diffusion-based generative model bypasses the need for manual map interpretation, producing chemically plausible crystal structures conditioned on the diffraction pattern. We demonstrate that XDXD achieves a 70.4\% match rate for structures with data limited to 2.0~\AA{} resolution, with a root-mean-square error (RMSE) below 0.05. Evaluated on a benchmark of 24,000 experimental structures, our model proves to be robust and accurate. Furthermore, a case study on small peptides highlights the model's potential for extension to more complex systems, paving the way for automated structure solution in previously intractable cases.

Authors (7)

Jiale Zhao

Cong Liu

Yuxuan Zhang

Chengyue Gong

Zhenyi Zhang

Shifeng Jin

+1 more

Submitted

October 20, 2025

arXiv Category

cond-mat.mtrl-sci

arXiv PDF

Key Contributions

XDXD is the first end-to-end deep learning framework that directly determines a complete atomic model from low-resolution single-crystal X-ray diffraction data. Utilizing a diffusion-based generative model, it bypasses the challenging manual interpretation of electron density maps, producing chemically plausible crystal structures directly from diffraction patterns.

Business Value

Accelerates materials discovery and development by enabling rapid and accurate determination of crystal structures from limited experimental data, crucial for fields like pharmaceuticals and advanced materials.

Paper Metadata

Innovation Type

Algorithmic

Deployment Feasibility

Moderate. Requires specialized expertise for X-ray diffraction data acquisition and processing, but the deep learning framework itself could be integrated into existing workflows.

Limitations Addressed

Addresses the significant challenge of determining crystal structures when X-ray diffraction data is limited to low resolution. Overcomes the ambiguity and difficulty in interpreting low-resolution electron density maps produced by traditional methods.

Performance Gains

Achieves a 70.4% match rate for structures with data limited to 2.0 Å resolution, with an RMSE below 0.05, outperforming previous methods that struggle with low-resolution data.

Technical Tags

crystal structure determinationX-ray diffractionlow resolution datadeep learningend-to-end frameworkdiffusion modelgenerative modelatomic modelcrystallographic phase problemelectron density maps

Research Topics

Materials ScienceCrystallographyDeep LearningGenerative ModelsScientific Computing

Methods & Architectures

End-to-end Deep LearningDiffusion-based Generative ModelX-ray Diffraction Data Analysis Diffusion ModelGenerative Model

Applications & Tasks

Materials Science Chemistry Drug Discovery Physics Crystal Structure DeterminationSolving Crystallographic Phase ProblemInterpreting Low-Resolution Data Determining complete atomic models directly from low-resolution X-ray diffraction dataBypassing manual interpretation of electron density maps

Related Fields

Materials ScienceComputational ChemistryMachine LearningScientific Imaging

Keywords

crystal structure determinationX-ray diffractionlow resolutiondeep learninggenerative modelsdiffusion modelsatomic modelcrystallographyphase problemelectron density mapmaterials sciencechemistryend-to-endcomputational

Academic Context

#Materials Science#Crystallography#Deep Learning#Generative Models#Scientific Computing

Commercial Potential

Potential Products

Automated crystal structure analysis softwareMaterials design platformsDrug discovery acceleration tools

Target Industries

PharmaceuticalsMaterials ScienceChemicalsSemiconductorsBiotechnology

Use Case Examples

Rapidly determining the structure of a new drug candidateIdentifying the atomic arrangement of novel materials for energy applicationsCharacterizing unknown crystalline substances in forensic science

Competitive Edge

Provides a novel end-to-end solution for low-resolution X-ray diffraction data, overcoming limitations of traditional methods that rely on manual interpretation and struggle with data quality.

Market Opportunity

Significant market for materials discovery and drug development tools.

Revenue Models

Software licensingcloud-based analysis services.

Resource Requirements

Compute Needs

Moderate to High, depending on the size and complexity of the crystal structures and the diffusion model training.

Data Requirements

Low-resolution single-crystal X-ray diffraction data.

Deployment Constraints

Requires expertise in crystallography and X-ray diffraction data processing.

Scalability

Scalability depends on the diffusion model architecture and computational resources available for training and inference.

Production Readiness

Maturity Level

Research

Time to Market

2-4 years

Patent Potential

Moderate, for the specific diffusion model architecture and end-to-end framework.

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