Dynamic model of supersonic martensitic crystal growth

The basic features of martensitic transformations are reviewed using the fcc—bcc (bct) transformation in iron alloys as an example. Supersonic crystal growth is believed to be due to a master wave process initiated by an excited (oscillatory) state that arises in the elastic field of a dislocation. Topics discussed include the mechanism by which nonequilibrium electrons generate (amplify) master waves; the optimum range of parameters for wave generation; the dependence of the transformation onset temperature on the polycrystal size; and the formation of transformation twins due to the coordinated action of relatively short and relatively long wavelength waves. Future research prospects are briefly discussed.

PACS: 63.20.−e, 64.70.K−, 81.30.Kf (all)
DOI: 10.3367/UFNe.0181.201104a.0345
URL: https://ufn.ru/en/articles/2011/4/a/
Web of Science

000294814800001
Scopus

2-s2.0-79960913909
ADS NASA

2011PhyU...54..331K
Citation: Kashchenko M P, Chashchina V G "Dynamic model of supersonic martensitic crystal growth" Phys. Usp. 54 331–349 (2011)

BibTexBibNote ® (generic)BibNote ® (RIS)MedlineRefWorks

Received: 17th, July 2010, revised: 15th, September 2010, accepted: 21st, September 2010

Оригинал: Кащенко М П, Чащина В Г «Динамическая модель сверхзвукового роста мартенситных кристаллов» УФН 181 345–364 (2011); DOI: 10.3367/UFNr.0181.201104a.0345

References (150) Cited by (62) Similar articles (20) ↓

S.V. Dmitriev, E.A. Korznikova et al “Discrete breathers in crystals” 59 446–461 (2016)
Yu.S. Nechaev “The distribution of carbon in steels” 54 465–471 (2011)
A.L. Roitburd “The theory of the formation of a heterophase structure in phase transformations in solids” 17 326–344 (1974)
A.N. Vasil’ev, V.D. Buchel’nikov et al “Shape memory ferromagnets” 46 559–588 (2003)
Yu.I. Ustinovshchikov “Pairwise interatomic interaction in alloys” 63 668–682 (2020)
I.K. Razumov, A.Y. Yermakov et al “Nonequilibrium phase transformations in alloys under severe plastic deformation” 63 733–757 (2020)
A.P. Zhernov, A.V. Inyushkin “Effect of isotopic composition on phonon modes. Static atomic displacements in crystals” 44 785–811 (2001)
Yu.A. Izyumov, E.Z. Kurmaev “Physical properties and electronic structure of superconducting compounds with the β-tungsten structure” 17 356–380 (1974)
P.A. Alekseev “Neutron spectroscopy and strongly correlated electrons: a view from the inside” 60 58–90 (2017)
O.Yu. Belyaeva, L.K. Zarembo, S.N. Karpachev “Magnetoacoustics of ferrites and magnetoacoustic resonance” 35 (2) 106–122 (1992)
A.I. Olemskoi, I.V. Koplyk “The theory of spatiotemporal evolution of nonequilibrium thermodynamic systems” 38 1061–1097 (1995)
A.V. Nikolaev, A.V. Tsvyashchenko “The puzzle of the γ→α and other phase transitions in cerium” 55 657–680 (2012)
A.A. Ishchenko, S.A. Aseev et al “Ultrafast electron diffraction and electron microscopy: present status and future prospects” 57 633–669 (2014)
P.A. Alekseev “High borides: determining the features and details of lattice dynamics from neutron spectroscopy” 58 330–344 (2015)
A.N. Utyuzh, A.V. Mikheyenkov “Hydrogen and its compounds under extreme pressure” 60 886–901 (2017)
L.A. Falkovsky “Investigation of semiconductors with defects using Raman scattering” 47 249–272 (2004)
S.M. Stishov, A.E. Petrova “Thermodynamic, elastic, and electronic properties of substances with a chiral crystal structure: MnSi, FeSi, and CoSi” 66 576–585 (2023)
A.V. Baranov, Ya.S. Bobovich, V.I. Petrov “Spectroscopy of resonance hyper-Raman scattering of light” 33 (10) 812–832 (1990)
G.L. Belen’kii, E.Yu. Salaev, R.A. Suleimanov “Deformation effects in layer crystals” 31 434–455 (1988)
V.G. Bar’yakhtar, B.A. Ivanov, M.V. Chetkin “Dynamics of domain walls in weak ferromagnets” 28 563–588 (1985)

The list is formed automatically.