March 29, 2019
Book Chapter

ADVANCED-STEM-BASED DEEP LEARNING FOR SEMANTIC SEGMENTATION OF DEFECTS IN STEELS

Abstract

In this work, we developed a novel deep convolutional neural network (DCNN) model, called DefectNet, for robust and automated semantic segmentation of three crystallographic defects including line dislocations, precipitates and voids commonly observed in structural metals and alloys. In previous work, we established an experimental protocol for a diffraction contrast imaging scanning transmission electron microscopy (DCI STEM) technique and tailored it specifically for imaging defects in popular iron-based structural alloy. Thus, the DefectNet was trained over a small but high-quality DCI STEM defect image sets of a HT-9 martensitic steel before and after neutron irradiation for 111.8 dpa at 412°C. For the defect quantification that typically takes at least half an hour even for an expert, with a good model the machine learning algorithm can produce more reproducible and reliable quantification in a few seconds. This work demonstrates the feasibility of using deep learning algorithms for fast and accurate defect quantitative analysis.

Revised: October 3, 2019 | Published: March 29, 2019

Citation

Zhu Y., G.W. Roberts, R. Sainju, B.J. Hutchinson, R.J. Kurtz, M.B. Toloczko, and D.J. Edwards, et al. 2019. ADVANCED-STEM-BASED DEEP LEARNING FOR SEMANTIC SEGMENTATION OF DEFECTS IN STEELS. In Fusion Materials Semiannual Progress Report for the Period Ending December 31, 2018, edited by F.W. Wiffen and S. Melton. 83-84. DOE-ER-0313/65. Oak Ridge, Tennessee:Oak Ridge National Laboratory. PNNL-SA-141280.