EPMA quantification on the chemical composition of retained austenite in a Fe-Mn-Si-C-based multi-phase steel

Yoon-Uk Heo; Chang-Gon Jeong; Soo-Hyun Kim; Gun-Young Yoon; T T T Trang; Youngyun Woo; Eun Yoo Yoon; Young-Seon Lee

doi:10.1186/s42649-022-00083-0

EPMA quantification on the chemical composition of retained austenite in a Fe-Mn-Si-C-based multi-phase steel

Appl Microsc. 2022 Dec 20;52(1):14. doi: 10.1186/s42649-022-00083-0.

Authors

Yoon-Uk Heo¹, Chang-Gon Jeong², Soo-Hyun Kim², Gun-Young Yoon³, T T T Trang², Youngyun Woo³, Eun Yoo Yoon³, Young-Seon Lee³

Affiliations

¹ Graduate Institute of Ferrous and Energy Materials Technology, Pohang University of Science and Technology, Cheongam-Ro 77, Hyoja dong, Pohang, 37-673, Republic of Korea. yunuk01@postech.ac.kr.
² Graduate Institute of Ferrous and Energy Materials Technology, Pohang University of Science and Technology, Cheongam-Ro 77, Hyoja dong, Pohang, 37-673, Republic of Korea.
³ Korea Institute for Materials Science, 797 Changwon-daero, Seongsan-gu, Changwon, 51508, Republic of Korea.

Abstract

An electron probe X-ray microanalyzer (EPMA) is an essential tool for studying chemical composition distribution in the microstructure. Quantifying chemical composition using standard specimens is commonly used to determine the composition of individual phases. However, the local difference in chemical composition in the standard specimens brings the deviation of the quantified composition from the actual one. This study introduces how to overcome the error of quantification in EPMA in the practical aspect. The obtained results are applied to evaluate the chemical composition of retained austenite in multi-phase steel. Film-type austenite shows higher carbon content than blocky-type one. The measured carbon contents of the retained austenite show good coherency with the calculated value from the X-ray diffraction.

Keywords: Carbon content; EPMA quantification; Multi-phase steel; Retained austenite; XRD.