Accelerating Discovery of Atomistic Defects via Machine Learning

Grace Guinan; Michelle Smeaton; Hilary Egan; Andrew Glaws; Brian Wyatt; Babak Anasori; Steven Spurgeon

Accelerating Discovery of Atomistic Defects via Machine Learning

Grace Guinan, Michelle Smeaton, Hilary Egan, Andrew Glaws, Brian Wyatt, Babak Anasori, Steven Spurgeon

Purdue University

Research output: NREL › Poster

Abstract

The quantification of defects such as vacancies in crystalline structures is a cornerstone of materials science research. Traditional efforts often rely on manual detection, a process that is time-intensive, prone to human error, and challenging to scale. Here we leverage machine learning (ML) methods to identify and quantify vacancies within a crystalline lattice, aiming to expedite detection while improving accuracy. Additionally, we explore the transferability of these ML techniques, identifying characteristics of atomistic imaging data that complicate this task. We show how the integration of ML can drive innovation, providing a powerful tool that will play an increasingly crucial role in the future of materials science.

Original language	American English
Publisher	National Renewable Energy Laboratory (NREL)
Number of pages	1
State	Published - 2025

Publication series

Name	Presented at the Electronic Materials and Applications (EMA 2025) Meeting, 25-28 February 2025, Denver, Colorado

NREL Publication Number

NREL/PO-5K00-92806

Keywords

2D materials
computer vision
machine learning
mxenes
point defects
scanning transmission electron microscopy

Access to Document

https://www.nrel.gov/docs/fy26osti/92806.pdf

Cite this

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title = "Accelerating Discovery of Atomistic Defects via Machine Learning",

abstract = "The quantification of defects such as vacancies in crystalline structures is a cornerstone of materials science research. Traditional efforts often rely on manual detection, a process that is time-intensive, prone to human error, and challenging to scale. Here we leverage machine learning (ML) methods to identify and quantify vacancies within a crystalline lattice, aiming to expedite detection while improving accuracy. Additionally, we explore the transferability of these ML techniques, identifying characteristics of atomistic imaging data that complicate this task. We show how the integration of ML can drive innovation, providing a powerful tool that will play an increasingly crucial role in the future of materials science.",

keywords = "2D materials, computer vision, machine learning, mxenes, point defects, scanning transmission electron microscopy",

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year = "2025",

language = "American English",

series = "Presented at the Electronic Materials and Applications (EMA 2025) Meeting, 25-28 February 2025, Denver, Colorado",

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T1 - Accelerating Discovery of Atomistic Defects via Machine Learning

AU - Guinan, Grace

AU - Smeaton, Michelle

AU - Egan, Hilary

AU - Glaws, Andrew

AU - Wyatt, Brian

AU - Anasori, Babak

AU - Spurgeon, Steven

PY - 2025

Y1 - 2025

N2 - The quantification of defects such as vacancies in crystalline structures is a cornerstone of materials science research. Traditional efforts often rely on manual detection, a process that is time-intensive, prone to human error, and challenging to scale. Here we leverage machine learning (ML) methods to identify and quantify vacancies within a crystalline lattice, aiming to expedite detection while improving accuracy. Additionally, we explore the transferability of these ML techniques, identifying characteristics of atomistic imaging data that complicate this task. We show how the integration of ML can drive innovation, providing a powerful tool that will play an increasingly crucial role in the future of materials science.

AB - The quantification of defects such as vacancies in crystalline structures is a cornerstone of materials science research. Traditional efforts often rely on manual detection, a process that is time-intensive, prone to human error, and challenging to scale. Here we leverage machine learning (ML) methods to identify and quantify vacancies within a crystalline lattice, aiming to expedite detection while improving accuracy. Additionally, we explore the transferability of these ML techniques, identifying characteristics of atomistic imaging data that complicate this task. We show how the integration of ML can drive innovation, providing a powerful tool that will play an increasingly crucial role in the future of materials science.

KW - 2D materials

KW - computer vision

KW - machine learning

KW - mxenes

KW - point defects

KW - scanning transmission electron microscopy

M3 - Poster

T3 - Presented at the Electronic Materials and Applications (EMA 2025) Meeting, 25-28 February 2025, Denver, Colorado

PB - National Renewable Energy Laboratory (NREL)

ER -