arxiv_cv 85% Match Research Paper Materials Scientists,Microscopists,Researchers in Crystallography,Machine Learning Engineers 2 days ago

Generative diffusion modeling protocols for improving the Kikuchi pattern indexing in electron back-scatter diffraction

generative-ai › diffusion

📄 Abstract

Abstract: Electron back-scatter diffraction (EBSD) has traditionally relied upon methods such as the Hough transform and dictionary Indexing to interpret diffraction patterns and extract crystallographic orientation. However, these methods encounter significant limitations, particularly when operating at high scanning speeds, where the exposure time per pattern is decreased beyond the operating sensitivity of CCD camera. Hence the signal to noise ratio decreases for the observed pattern which makes the pattern noisy, leading to reduced indexing accuracy. This research work aims to develop generative machine learning models for the post-processing or on-the-fly processing of Kikuchi patterns which are capable of restoring noisy EBSD patterns obtained at high scan speeds. These restored patterns can be used for the determination of crystal orientations to provide reliable indexing results. We compare the performance of such generative models in enhancing the quality of patterns captured at short exposure times (high scan speeds). An interesting observation is that the methodology is not data-hungry as typical machine learning methods.

Authors (2)

Meghraj Prajapat

Alankar Alankar

Submitted

October 30, 2025

arXiv Category

cond-mat.mtrl-sci

arXiv PDF

Key Contributions

This research develops generative diffusion models to restore noisy Kikuchi patterns obtained at high scanning speeds in EBSD. By enhancing the quality of these patterns, the models enable more reliable determination of crystal orientations, overcoming limitations of traditional methods like Hough transform and dictionary indexing.

Business Value

Accelerates materials characterization by enabling faster EBSD data acquisition without sacrificing accuracy, leading to quicker discovery and development of new materials.

Paper Metadata

Innovation Type

Application of Generative Models

Deployment Feasibility

Moderate, requires integration into EBSD data acquisition and analysis software.

Limitations Addressed

Significant limitations in traditional EBSD pattern indexing methods (Hough transform, dictionary indexing) at high scanning speeds, leading to reduced signal-to-noise ratio and lower indexing accuracy due to noisy patterns.

Performance Gains

Improved quality of Kikuchi patterns, leading to more reliable indexing results.

Technical Tags

generative modelsdiffusion modelsKikuchi pattern indexingEBSDelectron microscopynoise reductionpattern restorationcrystallography

Research Topics

Generative ModelingElectron Backscatter Diffraction (EBSD)Materials ScienceImage Restoration

Methods & Architectures

Generative diffusion modelingKikuchi pattern enhancementPost-processingOn-the-fly processing Generative Diffusion Models

Applications & Tasks

Materials Science Electron Microscopy Crystallography Scientific Imaging Improving EBSD AccuracyHandling Noisy Diffraction PatternsHigh-Speed Data Acquisition Kikuchi Pattern IndexingCrystal Orientation DeterminationRestoring Noisy EBSD Patterns

Related Fields

Materials ScienceMachine LearningImage ProcessingScientific Instrumentation

Keywords

generative modelsdiffusion modelsKikuchi patternEBSDelectron microscopynoise reductionpattern restorationcrystallographymaterials scienceindexinghigh speed

Academic Context

#Generative Modeling#Electron Backscatter Diffraction (EBSD)#Materials Science#Image Restoration

Commercial Potential

Potential Products

EBSD analysis software with AI-powered denoisingTools for accelerated materials characterizationLibraries for generative pattern restoration

Target Industries

Materials Science and EngineeringSemiconductorsAerospaceAutomotive

Use Case Examples

Rapidly determining crystal structures of new alloysAnalyzing microstructural defects in manufactured componentsAccelerating the discovery of novel functional materials

Competitive Edge

Applies advanced generative diffusion models to a specific problem in materials science (EBSD), offering a potentially more effective solution than traditional signal processing techniques for noisy patterns.

Market Opportunity

Significant market for materials characterization tools and techniques.

Revenue Models

Licensing of softwareintegration services for microscopy equipment manufacturers.

Resource Requirements

Compute Needs

Requires GPU for training diffusion models.

Data Requirements

Requires EBSD Kikuchi patterns, ideally with ground truth or varying noise levels.

Deployment Constraints

Integration with existing EBSD hardware and software.

Scalability

Scalability depends on the efficiency of the diffusion model and the processing pipeline.

Production Readiness

Maturity Level

Research

Time to Market

Medium (requires integration and validation with EBSD systems)

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