Journal Article10.1016/J.MSEA.2008.05.042
Microband-induced plasticity in a high Mn–Al–C light steel
Je Doo Yoo,Kyung-Tae Park +1 more
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TL;DR: In this article, room temperature tensile behavior of a high Mn-Al-C steel in the solid solution state was correlated to the microstructures developed during plastic deformation in order to clarify the dominant deformation mechanisms.
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Abstract: Room temperature tensile behavior of a high Mn–Al–C steel in the solid solution state was correlated to the microstructures developed during plastic deformation in order to clarify the dominant deformation mechanisms. The steel was fully austenitic with a fairly high stacking fault energy of ∼85 mJ/m 2 . The tensile behavior of the steel was manifested by an excellent combination of strength and ductility over 80,000 MPa% in association with continuous strain hardening to the high strain. In addition, the austenite phase was very stable during deformation. The high stacking fault energy and firm stability of austenite were attributed to the high Al content. In spite of the high stacking fault energy, deformed microstructures exhibited the planar glide characteristics, seemingly due to the glide plane softening effect. In the process of straining, the formation of crystallographic microbands and their intersections dominantly occurred. Microbands consisting of geometrically necessary dislocations led to the high total dislocation density state during deformation, resulting in continuous strain hardening. This microband-induced plasticity is to be the origin of the enhanced mechanical properties of the steel.
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Citations
Enhanced strength and ductility in a high-entropy alloy via ordered oxygen complexes
Zhifeng Lei,Xiongjun Liu,Yuan Wu,Hui Wang,Suihe Jiang,S. D. Wang,Xidong Hui,Yidong Wu,Baptiste Gault,Paraskevas Kontis,Dierk Raabe,Lin Gu,Qinghua Zhang,Houwen Chen,Hongtao Wang,Jiabin Liu,Ke An,Qiaoshi Zeng,T.G. Nieh,Zhaoping Lu +19 more
TL;DR: It is shown that oxygen can take the form of ordered oxygen complexes, a state in between oxide particles and frequently occurring random interstitials, which lead to unprecedented enhancement in both strength and ductility in compositionally complex solid solutions, the so-called high-entropy alloys (HEAs).
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Current state of Fe-Mn-Al-C low density steels
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