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Low-oxygen rare earth steels

Authors :
Dianzhong Li
Pei Wang
Xing-Qiu Chen
Paixian Fu
Yikun Luan
Xiaoqiang Hu
Hongwei Liu
Mingyue Sun
Yun Chen
Yanfei Cao
Leigang Zheng
Jinzhu Gao
Yangtao Zhou
Lei Zhang
Xiuliang Ma
Chunli Dai
Chaoyun Yang
Zhonghua Jiang
Yang Liu
Yiyi Li
Source :
Nature Materials. 21:1137-1143
Publication Year :
2022
Publisher :
Springer Science and Business Media LLC, 2022.

Abstract

Rare earth (RE) addition to steels to produce RE steels has been widely applied when aiming to improve steel properties. However, RE steels have exhibited extremely variable mechanical performances, which has become a bottleneck in the past few decades for their production, utilization and related study. Here in this work, we discovered that the property variation of RE steels stems from the presence of oxygen-based inclusions. We proposed a dual low-oxygen technology, and keeping low levels of oxygen content in steel melts and particularly in the raw RE materials, which have long been ignored, to achieve impressively stable and favourable RE effects. The fatigue life is greatly improved by only parts-per-million-level RE addition, with a 40-fold improvement for the tension-compression fatigue life and a 40% enhancement of the rolling contact fatigue life. We find that RE appears to act by lowering the carbon diffusion rate and by retarding ferrite nucleation at the austenite grain boundaries. Our study reveals that only under very low-oxygen conditions can RE perform a vital role in purifying, modifying and micro-alloying steels, to improve the performance of RE steels.

Details

ISSN :
14764660 and 14761122
Volume :
21
Database :
OpenAIRE
Journal :
Nature Materials
Accession number :
edsair.doi.dedup.....2d4af89814a275ba6b33c8762db21daf