Atomic Order and Submicrostructure in Iron Alloys at Megaplastic Deformation
Abstract
:1. Introduction
2. Dynamic Short-Range Clustering in Supersaturated Iron Alloys upon Megaplastic Deformation
2.1. Acceleration of Short-Range Clustering in the Binary Alloys Fe–Mn(Cr,Ni) at “Warm” Megaplastic Deformation
2.2. The Mechanism and Kinetics of Deformation-Induced Ordering in Iron Alloys. A Comparison with the Case of Irradiation by High-Energy Electrons
3. The Formation of Submicrostructure in High-Nitrogen Fe-Cr-N and High-Carbon Fe-Ni-C Steels upon Megaplastic Deformation
3.1. The Effect of Deformation Temperature on the Dissolution and Precipitation of Nitrides and Carbides in Steels
3.2. The Regulation of the Chemical Composition of Dispersion-Hardened Steels at Megaplastic Deformation
4. Mechanical Alloying in Aging FCC Fe-Ni-Me (Me = Ti, Al, Si, Zr) Alloys
4.1. The Effect of the Temperature and Rate of Megaplastic Deformation on the Structural Transformations in Austenitic Fe-Ni-Me Alloys. A Phenomenological Model of Mechanical Alloying
4.2. The Effect of the Activity of Chemical Elements on the Kinetics of Mechanical Alloying. Dual Nature of Dissolution of Intermetallic Particles (i) upon Deformation and (ii) in the Cascades of Atomic Displacements upon Irradiation by Fast Neutrons
5. The Modification of the Structure and Properties in Steel with Employment of Megaplastic Deformation (Conclusion)
Author Contributions
Funding
Acknowledgments
Conflicts of Interest
References
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Shabashov, V.; Sagaradze, V.; Kozlov, K.; Ustyugov, Y. Atomic Order and Submicrostructure in Iron Alloys at Megaplastic Deformation. Metals 2018, 8, 995. https://doi.org/10.3390/met8120995
Shabashov V, Sagaradze V, Kozlov K, Ustyugov Y. Atomic Order and Submicrostructure in Iron Alloys at Megaplastic Deformation. Metals. 2018; 8(12):995. https://doi.org/10.3390/met8120995
Chicago/Turabian StyleShabashov, Valery, Victor Sagaradze, Kirill Kozlov, and Yury Ustyugov. 2018. "Atomic Order and Submicrostructure in Iron Alloys at Megaplastic Deformation" Metals 8, no. 12: 995. https://doi.org/10.3390/met8120995