"Some Features of γ-ε Martensitic Transformation and Shape Memory Effect in Fe-Mn-Si Based alloys"

Gulyaev, A. A.

doi:10.1051/jp4:1995871

Cited by 6 publications

(4 citation statements)

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“…On the other hand, Andersson et al [11] showed that it is possible to form a large amount of e martensite even when the c has undergone antiferromagnetic transition, as in the case of M S < T N . Gulyaev [12] reported that the addition of Si significantly enhances the yield strength (YS) from 180 MPa for Fe-30Mn to 350 MPa for Fe-30Mn-5.5Si. It is also well known that Si lowers the SFE of the c phase, [13] which favors the formation of e martensite.…”

Section: Introductionmentioning

confidence: 99%

Role of Si in Improving the Shape Recovery of FeMnSiCrNi Shape Memory Alloys

Maji

Krishnan

Gouthama

et al. 2011

Metall Mater Trans A

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The effect of Si addition on the microstructure and shape recovery of FeMnSiCrNi shape memory alloys has been studied. The microstructural observations revealed that in these alloys the microstructure remains single-phase austenite (c) up to 6 pct Si and, beyond that, becomes two-phase c + d ferrite. The Fe 5 Ni 3 Si 2 type intermetallic phase starts appearing in the microstructure after 7 pct Si and makes these alloys brittle. Silicon addition does not affect the transformation temperature and mechanical properties of the c phase until 6 pct, though the amount of shape recovery is observed to increase monotonically. Alloys having more than 6 pct Si show poor recovery due to the formation of d-ferrite. The shape memory effect (SME) in these alloys is essentially due to the c to stress-induced e martensite transformation, and the extent of recovery is proportional to the amount of stress-induced e martensite. Alloys containing less than 4 pct and more than 6 pct Si exhibit poor recovery due to the formation of stress-induced a¢ martensite through c-e-a¢ transformation and the large volume fraction of d-ferrite, respectively. Silicon addition decreases the stacking fault energy (SFE) and the shear modulus of these alloys and results in easy nucleation of stress-induced e martensite; consequently, the amount of shape recovery is enhanced. The amount of athermal e martensite formed during cooling is also observed to decrease with the increase in Si.

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Section: Introductionmentioning

confidence: 99%

Role of Si in Improving the Shape Recovery of FeMnSiCrNi Shape Memory Alloys

Maji

Krishnan

Gouthama

et al. 2011

Metall Mater Trans A

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“…In this regard, Fe-Mn alloys doped with silicon are of great practical interest. At a certain manganese content (28–33 wt %), the introduction of 4–6 wt % Si to the alloy composition leads not only to the hardening of the alloys [ 18 ] but also facilitates the realization of the shape memory effect [ 17 , 19 , 20 ]. Moreover, the heat treatment of the Fe-30Mn-5Si alloy [ 17 ], which ensured the stabilization of the martensitic structure, made it possible to significantly reduce the martensitic start ( M s ) and finish ( M f ) temperatures: 60 °C and below 60 °C, respectively, in comparison with the Fe-(23-26)Mn-5Si.…”

Section: Introductionmentioning

confidence: 99%

Effect of Thermomechanical Treatment on Structure and Functional Fatigue Characteristics of Biodegradable Fe-30Mn-5Si (wt %) Shape Memory Alloy

et al. 2021

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The Fe-Mn-Si shape memory alloys are considered promising materials for the biodegradable bone implant application since their functional properties can be optimized to combine bioresorbability with biomechanical and biochemical compatibility with bone tissue. The present study focuses on the fatigue and corrosion fatigue behavior of the thermomechanically treated Fe-30Mn-5Si (wt %) alloy compared to the conventionally quenched alloy because this important functionality aspect has not been previously studied. Hot-rolled and water-cooled, cold-rolled and annealed, and conventionally quenched alloy samples were characterized by X-ray diffraction, transmission electron microscopy, tensile fatigue testing in air atmosphere, and bending corrosion fatigue testing in Hanks’ solution. It is shown that hot rolling at 800 °C results in the longest fatigue life of the alloy both in air and in Hanks’ solution. This advantage results from the formation of a dynamically recrystallized γ-phase grain structure with a well-developed dislocation substructure. Another important finding is the experimental verification of Young’s modulus anomalous temperature dependence for the studied alloy system, its minimum at a human body temperature, and corresponding improvement of the biomechanical compatibility. The idea was realized by lowering Ms temperature down to the body temperature after hot rolling at 800 °C.

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“…NiTi alloys, Cu-based and Fe-based alloys are the most well known types of SMAs. Based on their crystalline structure in the austenitic phase they are grouped in “β-type” with body centered cubic (bcc) cell structure, a subclass of them being Ni-Ti [ 1 ], Co-Ni-Ga [ 2 , 3 , 4 ], Cu-Zn-Al, Cu-Al-Ni [ 5 ] and Ni-Mn-Ga [ 6 , 7 , 8 ], Ni-Fe-Ga Heusler alloys [ 8 , 9 ] and “γ-type”, with face centered cubic (fcc) cell structure, comprising Fe-Mn and Fe-Mn-Si [ 10 , 11 ], FePd [ 12 ] or FeNiCoTi [ 13 ]. Among these, Fe-Mn shape memory alloys present a good workability, weldability, corrosion resistance [ 14 ], large damping effect [ 15 ], recovery strain due to the shape memory effect (SME) [ 16 ] and superelasticity [ 17 , 18 ].…”

Section: Introductionmentioning

confidence: 99%

“…It has been shown that addition of Si atoms enhances reversibility of martensite and the shape memory effect in the Fe-Mn alloys [ 16 ], while the Cr addition (between 5 and 9 wt.%) improves the corrosion resistance of Fe-Mn-Si alloys [ 19 ]. The MT of Fe-Mn-Si alloys shows a particular non-thermoelastic stress-induced γ‒ε martensitic transformation and its ε‒γ reverse transformation during subsequent heating [ 10 , 11 , 14 , 15 , 16 , 17 , 18 , 19 , 20 , 21 ]. Additionally, beside ε-martensite (hexagonal close packed—hcp—stress-induced structure), the α’-martensite (body-centred-tetragonal—bct—structure) may appear at the intersections of crystallographic defects induced by plastic deformation such as mechanical twins, stacking faults and shear bands [ 22 , 23 ].…”

Section: Introductionmentioning

confidence: 99%

The Effect of the In-Situ Heat Treatment on the Martensitic Transformation and Specific Properties of the Fe-Mn-Si-Cr Shape Memory Alloys Processed by HSHPT Severe Plastic Deformation

Gurău

Ţolea

et al. 2021

Materials

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This work focuses on the temperature evolution of the martensitic phase ε (hexagonal close packed) induced by the severe plastic deformation via High Speed High Pressure Torsion method in Fe57Mn27Si11Cr5 (at %) alloy. The iron rich alloy crystalline structure, magnetic and transport properties were investigated on samples subjected to room temperature High Speed High Pressure Torsion incorporating 1.86 degree of deformation and also hot-compression. Thermo-resistivity as well as thermomagnetic measurements indicate an antiferromagnetic behavior with the Néel temperature (TN) around 244 K, directly related to the austenitic γ-phase. The sudden increase of the resistivity on cooling below the Néel temperature can be explained by an increased phonon-electron interaction. In-situ magnetic and electric transport measurements up to 900 K are equivalent to thermal treatments and lead to the appearance of the bcc-ferrite-like type phase, to the detriment of the ε(hcp) martensite and the γ (fcc) austenite phases.

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"Some Features of γ-ε Martensitic Transformation and Shape Memory Effect in Fe-Mn-Si Based alloys"

Cited by 6 publications

References 0 publications

Role of Si in Improving the Shape Recovery of FeMnSiCrNi Shape Memory Alloys

Role of Si in Improving the Shape Recovery of FeMnSiCrNi Shape Memory Alloys

Effect of Thermomechanical Treatment on Structure and Functional Fatigue Characteristics of Biodegradable Fe-30Mn-5Si (wt %) Shape Memory Alloy

The Effect of the In-Situ Heat Treatment on the Martensitic Transformation and Specific Properties of the Fe-Mn-Si-Cr Shape Memory Alloys Processed by HSHPT Severe Plastic Deformation

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