Page 128 - Read Online
P. 128
Page 10 of 10 Lu et al. Microstructures 2023;3:2023033 https://dx.doi.org/10.20517/microstructures.2023.28
16. Dong G, Li S, Yao M, et al. Super-elastic ferroelectric single-crystal membrane with continuous electric dipole rotation. Science
2019;366:475-9. DOI
17. Condurache O, Dražić G, Sakamoto N, Rojac T, Benčan A. Atomically resolved structure of step-like uncharged and charged domain
walls in polycrystalline BiFeO . J Appl Phys 2021;129:054102. DOI
3
18. Simons H, Haugen AB, Jakobsen AC, et al. Long-range symmetry breaking in embedded ferroelectrics. Nat Mater 2018;17:814-9.
DOI
19. Jia C, Mi S, Urban K, Vrejoiu I, Alexe M, Hesse D. Atomic-scale study of electric dipoles near charged and uncharged domain walls
in ferroelectric films. Nat Mater 2008;7:57-61. DOI PubMed
20. Nataf GF, Aktas O, Granzow T, Salje EKH. Influence of defects and domain walls on dielectric and mechanical resonances in LiNbO .
3
J Phys Condens Matter 2016;28:015901. DOI PubMed
21. Miller RC, Weinreich G. Mechanism for the sidewise motion of 180° domain walls in barium titanate. Phys Rev 1960;117:1460-6.
DOI
22. Shin Y, Grinberg I, Chen I, Rappe AM. Nucleation and growth mechanism of ferroelectric domain-wall motion. Nature 2007;449:881-
4. DOI PubMed
23. Maerten L, Bojahr A, Gohlke M, Rössle M, Bargheer M. Coupling of GHz phonons to ferroelastic domain walls in SrTiO . Phys Rev
3
Lett 2015;114:047401. DOI PubMed
24. Anbusathaiah V, Nagarajan V, Aggarwal S. Nanoscale polarization relaxation kinetics in polycrystalline ferroelectric thin films. J Appl
Phys 2007;101:084104. DOI
25. Casals B, Nataf GF, Salje EKH. Avalanche criticality during ferroelectric/ferroelastic switching. Nat Commun 2021;12:345. DOI
PubMed PMC
26. Lu G, Li S, Ding X, Sun J, Salje EKH. Ferroelectric switching in ferroelastic materials with rough surfaces. Sci Rep 2019;9:15834.
DOI PubMed PMC
27. Salje EKH, Wang X, Ding X, Scott JF. Ultrafast switching in avalanche-driven ferroelectrics by supersonic kink movements. Adv
Funct Mater 2017;27:1700367. DOI
28. Salje EKH, Ishibashi Y. Mesoscopic structures in ferroelastic crystals: needle twins and right-angled domains. J Phys Condens Matter
1996;8:8477. DOI
29. Lee K, Baik S. Ferroelastic domain structure and switching in epitaxial ferroelectric thin films. Annu Rev Mater Res 2006;36:81-116.
DOI
30. Lu G, Ding X, Sun J, Salje EKH. Wall-wall and kink-kink interactions in ferroelastic materials. Phys Rev B 2022:106. DOI
31. Shilkrot LE, Srolovitz DJ. Elastic field of a surface step: atomistic simulations and anisotropic elastic theory. Phys Rev B
1996;53:11120. DOI
32. Andreev AF, Kosevich YK. Capillary phenomena in the theory of elasticity. J Exp Theor Phys 1981;54:761. Available from: http://
jetp.ras.ru/cgi-bin/e/index/e/54/4/p761?a=list [Last accessed on 9 August 2023]
33. Pertsev NA, Novak J, Salje EKH. Long-range elastic interactions and equilibrium shapes of curved ferroelastic domain walls in
crystals. Philos Mag A 2000;80:2201-13. DOI
34. Salje EKH, Ding X, Zhao Z, Lookman T, Saxena A. Thermally activated avalanches: jamming and the progression of needle domains.
Phys Rev B 2011;83:104109. DOI
35. Lu G, Li S, Ding X, Salje EKH. Piezoelectricity and electrostriction in ferroelastic materials with polar twin boundaries and domain
junctions. Appl Phys Lett 2019;114:202901. DOI
36. Ferrando R, Jellinek J, Johnston RL. Nanoalloys: from theory to applications of alloy clusters and nanoparticles. Chem Rev
2008;108:845-910. DOI PubMed
37. Nosé S. A unified formulation of the constant temperature molecular dynamics methods. J Chem Phys 1984;81:511-9. DOI
38. Stukowski A. Visualization and analysis of atomistic simulation data with OVITO-the open visualization tool. Model Simul Mater Sci
Eng 2010;18:015012. DOI
39. Shima H, Umeno Y, Sumigawa T. Analytic formulation of elastic field around edge dislocation adjacent to slanted free surface. R Soc
Open Sci 2022;9:220151. DOI PubMed PMC
40. Seifert U. Configurations of fluid membranes and vesicles. Adv Phys 1997;46:13-137. DOI
41. Nunes RW, Bennetto J, Vanderbilt D. Atomic structure of dislocation kinks in silicon. Phys Rev B 1998;57:10388-97. DOI
42. He X, Li S, Ding X, Sun J, Selbach SM, Salje EK. The interaction between vacancies and twin walls, junctions, and kinks, and their
mechanical properties in ferroelastic materials. Acta Mater 2019;178:26-35. DOI
43. Novak J, Salje EKH. Surface structure of domain walls. J Phys Condens Matter 1998;10:L359-66. DOI
44. Conti S, Salje EKH. Surface structure of ferroelastic domain walls: a continuum elasticity approach. J Phys Condens Matter
2001;13:L847-54. DOI
45. Gurrutxaga-Lerma B, Balint DS, Dini D, Sutton AP. Elastodynamic image forces on dislocations. Proc R Soc A 2015;471:20150433.
DOI PubMed PMC