SEM Investigation of High-Alloyed Austenitic Stainless Cast Steels With Varying Austenite Stability at Room Temperature and 100°C

The deformation mechanisms of high‐alloyed cast austenitic steels with 16% of chromium, 6% of manganese, and a nickel content of 3–9% were investigated by in situ and ex situ scanning electron microscopy. The austenite stability and the stacking fault energy were influenced by variation of the chemi...

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Veröffentlicht in:	Steel research international 2012-06, Vol.83 (6), p.512-520
Hauptverfasser:	Biermann, Horst, Solarek, Johannes, Weidner, Anja
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Sprache:	eng
Schlagworte:	austenitic steel martensitic transformation microstructure evolution stacking faults twinning
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creator	Biermann, Horst Solarek, Johannes Weidner, Anja
description	The deformation mechanisms of high‐alloyed cast austenitic steels with 16% of chromium, 6% of manganese, and a nickel content of 3–9% were investigated by in situ and ex situ scanning electron microscopy. The austenite stability and the stacking fault energy were influenced by variation of the chemical composition as well as by changing deformation temperature (room temperature; RT and 100°C). The study shows that both an increase in austenite stability and stacking fault energy yield a significant change in the deformation mechanisms. Both increase of nickel content and increase in deformation temperature reduce the intensity of the martensitic phase transformation. Thus, the steel with low nickel content shows at RT pronounced formation of α′‐martensite. The steel with the highest nickel content, however, shows pronounced twinning. The deformation mechanisms of high‐alloyed cast austenitic steels with 16% of chromium, 6% of manganese, and a nickel content of 3–9% at different temperatures were investigated by scanning electron microscopy. The intensity of the martensitic phase transformation is decreasing by increasing nickel concentration as well as deformation temperature. Thus, low nickel content leads at room temperature to a pronounced formation of α′‐martensite, whereas, the highest nickel content leads to a pronounced twinning.
doi_str_mv	10.1002/srin.201100293
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The austenite stability and the stacking fault energy were influenced by variation of the chemical composition as well as by changing deformation temperature (room temperature; RT and 100°C). The study shows that both an increase in austenite stability and stacking fault energy yield a significant change in the deformation mechanisms. Both increase of nickel content and increase in deformation temperature reduce the intensity of the martensitic phase transformation. Thus, the steel with low nickel content shows at RT pronounced formation of α′‐martensite. The steel with the highest nickel content, however, shows pronounced twinning. The deformation mechanisms of high‐alloyed cast austenitic steels with 16% of chromium, 6% of manganese, and a nickel content of 3–9% at different temperatures were investigated by scanning electron microscopy. The intensity of the martensitic phase transformation is decreasing by increasing nickel concentration as well as deformation temperature. 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subjects	austenitic steel martensitic transformation microstructure evolution stacking faults twinning
title	SEM Investigation of High-Alloyed Austenitic Stainless Cast Steels With Varying Austenite Stability at Room Temperature and 100°C
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