Shape Memory Effect Induced by Stress-induced α′ Martensite in a Metastable Fe-Cr-Ni Austenitic Stainless Steel

doi:10.1007/s40195-017-0571-x

Abstract

Abstract:

It is not clear whether a shape memory effect (SME) can be realized by stress-induced α′ martensite in metastable austenitic stainless steels although the stress-induced ε martensite in these materials can result in the SME. To clarify this problem, the relationship between the shape recovery and the reverse transformation of the stress-induced ε and α′ martensite in a 304 stainless steel was investigated. The results show that the stress-induced α′ martensite can result in the SME when heating above 773 K. After deformation at 77 K and step heating or directly holding at 1073 K, two-stage shape recoveries below 440 K and above 773 K can be obtained due to the reverse transformation of the stress-induced ε martensite and α′ martensite, respectively. After deformation at room temperature, the α′ martensite produced can result in the SME only when directly holding at 1073 K. The intrusion of more dislocations before the formation of the α′ martensite at room temperature than at 77 K is the reason that the α′martensite induced at room temperature cannot result in the SME in the case of slow heating. The recovered strains resulting from the stress-induced ε and α′ martensite are proportional to the amounts of their reverse transformation, respectively.

Key words: Austenitic stainless steel, Shape memory effect, Alpha prime martensite, Epsilon martensite, Two-stage recoveries

Yong-Ning Wang, Jie Chen, Hua-Bei Peng, Yu-Hua Wen. Shape Memory Effect Induced by Stress-induced α′ Martensite in a Metastable Fe-Cr-Ni Austenitic Stainless Steel[J]. Acta Metallurgica Sinica (English Letters), 2017, 30(6): 513-520.

Figures/Tables 7

Fig. 1 Recovered strain in 304 stainless steel after bending by 3.8% and 10% at 77 K a and height change after tensile deformation by 3.8% and 10% at 77 K b as functions of temperature, respectively

Fig. 2 Optical micrographs at room temperature of 304 stainless steel after cooling at 77 K a and after tensile deformation by 3.8% b and 10% c at 77 K

Fig. 3 In situ XRD patterns of 304 stainless steel after tensile deformation by 3.8% a, 10% b at 77 K and then step heating to different temperatures from room temperature. (The peaks of Al2O3 were from the protective cover of Al2O3)

Fig. 4 Effect of the heating temperature on the amount of α′ martensite in 304 stainless steel after tensile deformation by 3.8% and 10% at 77 K and then heated at different temperatures for 3 min. a, b magnetization curves; c magnetization at 15,000 Oe as a function of the heating temperature

Fig. 5 Relationship between recovered strains and magnetization at 15,000 Oe at room temperature in 304 stainless steel after deformation by 3.8% and 10% at 77 K and then heated at different temperatures, respectively

Fig. 6 Effects of deformation at room temperature on recovered strains and stress-induced martensitic transformation in 304 stainless steel. a Recovered strain after bending by 3.8% and 10% followed by step heating; XRD patterns after tensile deformation by 3.8% b, 10% c

Fig. 7 Bright-field images of transmission electron microscopy of 304 stainless steel after tensile deformation by 10% at room temperature a, 77 K b, respectively

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