L. Duprez
Primary tabs
Content
This is a debugging block
Race against the Machine: can deep learning recognize microstructures as well as the trained human eye?
Scripta Materialia
193, 33-37
2021
A1
Abstract
The promising results of deep learning in image recognition suggest a huge potential for microscopic analyses in materials science. One major challenge for its adoption in the study of materials is the limited number of images that are available to train models on. Herein, we present a methodology to create accurate image recognition models with small datasets. By explicitly taking into account the magnification and by introducing appropriate transformations, we incorporate as many insights from material science in the model as possible. This allows for a highly data-efficient training of complex deep learning models. Our results indicate that a model trained with the presented methodology is able to outperform human experts.
Private attachment
Compact representations of microstructure images using triplet networks
npj Computational Materials
6, 156
2020
A1
Abstract
The microstructure of a material, typically characterized through a set of microscopy images of two-dimensional cross-sections, is a valuable source of information about the material and its properties. Every pixel of the image is a degree of freedom causing the dimensionality of the information space to be extremely high. This makes it difficult to recognize and extract all relevant information from the images. Human experts circumvent this by manually creating a lower-dimensional representation of the microstructure. However, the question of how a microstructure image can be best represented remains open. From the field of deep learning, we present triplet networks as a method to build highly compact representations of the microstructure, condensing the relevant information into a much smaller number of dimensions. We demonstrate that these representations can be created even with a limited amount of example images, and that they are able to distinguish between visually very similar microstructures. We discuss the interpretability and generalization of the representations. Having compact microstructure representations, it becomes easier to establish processing–structure–property links that are key to rational materials design.
Open Access version available at UGent repositoryPrivate attachment
A first-principles reassessment of the Fe-N phase diagram in the low-nitrogen limit
Journal of Alloys and Compounds
775, 758-768
2019
A1
Inhibiting Hydrogen entry in repurposed pipelines for H2-transport
Predicting Phase Stability in Nitrogen Steels with Density-Functional Theory
Tue, 17/12/2019
Attachment (private)
Developing new iron-nitrogen steels with ab initio thermodynamics
A density-functional theory investigation of γ-Fe4N, α''-Fe16N2 and ε-Fe3N1+y precipitates in an Fe-N solid solution
ISBN/ISSN:
Talk
Conference / event / venue
EUROMAT 2017
Thessaloniki, Greece
Sunday, 17 September, 2017 to Friday, 22 September, 2017
Developing new iron-nitrogen steels with ab initio thermodynamics
A density-functional theory investigation of Fe4N and Fe16N2 precipitates in an Fe-N solid solution
68
ISBN/ISSN:
Poster
Conference / event / venue
ADIS 2016
Tegernsee, Germany
Monday, 3 October, 2016 to Friday, 7 October, 2016
Pages
Postscript First
This is a debugging block
Postscript Second
This is a debugging block
Postscript Third
This is a debugging block
Preface First
This is a debugging block
Preface Second
This is a debugging block
Preface Third
This is a debugging block