Conceptual Analysis on Severe Plastic Deformation Processes of Shape Memory Alloys: Mechanical Properties and Microstructure Characterization
Abstract
:1. Introduction
2. Influence of SPD Processing on the Shape Memory Effect
3. Effect of Different SPD Techniques on the Behavior of SMAs
3.1. Constrained Groove Pressing (CGP)
3.2. Equal-Channel Angular Pressing/Extrusion (ECAP/E)
3.3. High-Speed High-Pressure Torsion (HSHPT)
3.4. Local Canning Compression (LCC)
3.5. Accumulative Roll-Bonding (ARB)
4. Conclusions and Future Remarks
Author Contributions
Funding
Institutional Review Board Statement
Informed Consent Statement
Data Availability Statement
Conflicts of Interest
References
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No. | Type of SMAs | Type of SPD Technique | Application/Feature | Ref. |
---|---|---|---|---|
1 | Ti–Ni | Local canning compression | Amorphous structures | [56] |
2 | Ti–Ni | Local canning compression | Effect of the twins on the transformation behavior of the nanocrystalline NiTi | [57] |
3 | Ti–Ni | Local canning compression | Mechanisms of amorphization of NiTi SMA | [58] |
4 | Ti–Ni | High-pressure torsion | Structural investigations of nanostructured NiTi SMA | [59] |
5 | Ti–Ni | Equal-channel angular pressing | Viscoplastic FEM simulation, microstructural observation | [60] |
6 | Ti–Ni | High-pressure torsion Equal-channel angular pressing | Phase transformation sequence, microstructural studies | [61] |
7 | Ti–Ni | Equal-channel angular pressing | Phase transformation and precipitates’ behavior | [62] |
8 | Ti–Ni | Equal-channel angular pressing | Martensitic transformations and effect of second phases | [63] |
9 | Ti–Ni | Equal-channel angular pressing | Transformation behavior and effect of pass numbers | [64] |
10 | Ti–Ni | Equal-channel angular pressing | Phase transformation, microstructural observation | [65] |
11 | Ti–Ni | Equal-channel angular pressing | phase transformations and superelasticity | [66] |
12 | Ti50–Ni50, Ti49.5–Ni50.5, Ti50–Ni49–Fe1 | High-speed high-pressure torsion Equal-channel angular pressing | Phase transformation behavior | [67] |
13 | Ti–Nb–O | Equal-channel angular pressing | Superelastic behavior and precipitation effects | [68] |
14 | Ti–Mo | Equal-channel angular pressing | Martensitic transformations and effect of second phases | [63] |
15 | Cu–Al–Be–B | Equal-channel angular pressing | Microstructural observation | [69] |
16 | Cu–26Zn–5Al | Accumulative roll-bonding | Shape memory effect and phase distribution | [70] |
17 | Cu–Zn–Ni | Accumulative roll-bonding | Martensitic transformation and SMA behavior, microstructural observation | [31] |
18 | Cu–Al–Mn | Accumulative roll-bonding | Microstructure, phase formation, corrosion | [71] |
19 | Cu–Al–Mn alloys Cu–9.5Al–8.2Mn Cu–8.3Al–8Mn | Accumulative roll-bonding Equal-channel angular rolling | - | [72] |
20 | Fe–Mn–Si | High-speed high-pressure torsion | Magnetism | [73] |
21 | Fe–Mn–Si | High-speed high-pressure torsion | Actuator | [55] |
22 | Ni50.5–Ti49.5 | Constrained groove pressing | Biomedical | [34] |
23 | Ni57–Fe18–Ga25 | High-speed high-pressure torsion | Amorphization and magnetism | [74] |
24 | Ni50.3–Ti49.7 | High-speed high-pressure torsion | Smart hybrid material | [75] |
25 | Ni–Fe–Ga Ni57–Fe18–Ga25 | High-speed high-pressure torsion | Smart hybrid material | [75] |
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Ebrahimi, M.; Attarilar, S.; Gode, C.; Kandavalli, S.R.; Shamsborhan, M.; Wang, Q. Conceptual Analysis on Severe Plastic Deformation Processes of Shape Memory Alloys: Mechanical Properties and Microstructure Characterization. Metals 2023, 13, 447. https://doi.org/10.3390/met13030447
Ebrahimi M, Attarilar S, Gode C, Kandavalli SR, Shamsborhan M, Wang Q. Conceptual Analysis on Severe Plastic Deformation Processes of Shape Memory Alloys: Mechanical Properties and Microstructure Characterization. Metals. 2023; 13(3):447. https://doi.org/10.3390/met13030447
Chicago/Turabian StyleEbrahimi, Mahmoud, Shokouh Attarilar, Ceren Gode, Sumanth Ratna Kandavalli, Mahmoud Shamsborhan, and Qudong Wang. 2023. "Conceptual Analysis on Severe Plastic Deformation Processes of Shape Memory Alloys: Mechanical Properties and Microstructure Characterization" Metals 13, no. 3: 447. https://doi.org/10.3390/met13030447