Evidence of the monopolar‐dipolar crossover regime: a multiscale study of ferroelastic domains by in situ microscopy techniques

John J. R. Scott; Guangming Lu; Brian J. Rodriguez; Ian MacLaren; Ekhard K.H. Salje; Miryam Arredondo

doi:10.1002/smll.202400646

Evidence of the monopolar‐dipolar crossover regime: a multiscale study of ferroelastic domains by in situ microscopy techniques

John J. R. Scott^*, Guangming Lu^*, Brian J. Rodriguez, Ian MacLaren, Ekhard K.H. Salje, Miryam Arredondo^*

^*Corresponding author for this work

School of Mathematics and Physics

Research output: Contribution to journal › Article › peer-review

3 Citations (Scopus)

20 Downloads (Pure)

Abstract

The elastic interaction between kinks (and antikinks) within domain walls plays a pivotal role in shaping the domain structure, and their dynamics. In bulk materials, kinks interact as elastic monopoles, dependent on the distance between walls (d⁻¹) and typically characterized by a rigid and straight domain configuration. In this work the evolution of the domain structure is investigated, as the sample size decreases, by the means of in situ heating microscopy techniques on free-standing samples. As the sample size decreases, a significant transformation is observed: domain walls exhibit pronounced curvature, accompanied by an increase in both domain wall and junction density. This transformation is attributed to the pronounced influence of kinks, inducing sample warping, where “dipole–dipole” interactions are dominant (d⁻²). Moreover, a critical thickness range that delineates a crossover between the monopolar and dipolar regimens is experimentally identified and corroborated by atomic simulations. These findings are relevant for in situ TEM studies and for the development of novel devices based on free-standing ferroic thin films and nanomaterials.

Original language	English
Article number	2400646
Number of pages	10
Journal	Small
Volume	20
Issue number	35
Early online date	30 Apr 2024
DOIs	https://doi.org/10.1002/smll.202400646
Publication status	Published - 28 Aug 2024

Bibliographical note

Under review in Journal Small (Wiley-VCH)

Keywords

domain structure
domain wall curvature
ferroelastics
free‐standing samples
surface relaxation

Access to Document

10.1002/smll.202400646Licence: CC BY

Evidence of the monopolar‐dipolar crossover regime: a multiscale study of ferroelastic domains by in situ microscopy techniques
Copyright 2024 the authors. This is an open access article published under a Creative Commons Attribution License (https://creativecommons.org/licenses/by/4.0/), which permits unrestricted use, distribution and reproduction in any medium, provided the author and source are cited.
Final published version, 3.84 MBLicence: CC BY

Ferroelastic domain dynamics: a multiscale study through in situ microscopy
Scott, J. (Author), Arredondo, M. (Supervisor) & Gregg, M. (Supervisor), Jul 2024
Student thesis: Doctoral Thesis › Doctor of Philosophy

File

Cite this

@article{76aed9673bff48749582db0b3fbd177b,

title = "Evidence of the monopolar‐dipolar crossover regime: a multiscale study of ferroelastic domains by in situ microscopy techniques",

abstract = "The elastic interaction between kinks (and antikinks) within domain walls plays a pivotal role in shaping the domain structure, and their dynamics. In bulk materials, kinks interact as elastic monopoles, dependent on the distance between walls (d−1) and typically characterized by a rigid and straight domain configuration. In this work the evolution of the domain structure is investigated, as the sample size decreases, by the means of in situ heating microscopy techniques on free-standing samples. As the sample size decreases, a significant transformation is observed: domain walls exhibit pronounced curvature, accompanied by an increase in both domain wall and junction density. This transformation is attributed to the pronounced influence of kinks, inducing sample warping, where “dipole–dipole” interactions are dominant (d−2). Moreover, a critical thickness range that delineates a crossover between the monopolar and dipolar regimens is experimentally identified and corroborated by atomic simulations. These findings are relevant for in situ TEM studies and for the development of novel devices based on free-standing ferroic thin films and nanomaterials.",

keywords = "domain structure, domain wall curvature, ferroelastics, free‐standing samples, surface relaxation",

author = "Scott, {John J. R.} and Guangming Lu and Rodriguez, {Brian J.} and Ian MacLaren and Salje, {Ekhard K.H.} and Miryam Arredondo",

note = "Under review in Journal Small (Wiley-VCH)",

year = "2024",

month = aug,

day = "28",

doi = "10.1002/smll.202400646",

language = "English",

volume = "20",

journal = "Small",

issn = "1613-6810",

publisher = "Wiley-VCH Verlag",

number = "35",

}

TY - JOUR

T1 - Evidence of the monopolar‐dipolar crossover regime: a multiscale study of ferroelastic domains by in situ microscopy techniques

AU - Scott, John J. R.

AU - Lu, Guangming

AU - Rodriguez, Brian J.

AU - MacLaren, Ian

AU - Salje, Ekhard K.H.

AU - Arredondo, Miryam

N1 - Under review in Journal Small (Wiley-VCH)

PY - 2024/8/28

Y1 - 2024/8/28

N2 - The elastic interaction between kinks (and antikinks) within domain walls plays a pivotal role in shaping the domain structure, and their dynamics. In bulk materials, kinks interact as elastic monopoles, dependent on the distance between walls (d−1) and typically characterized by a rigid and straight domain configuration. In this work the evolution of the domain structure is investigated, as the sample size decreases, by the means of in situ heating microscopy techniques on free-standing samples. As the sample size decreases, a significant transformation is observed: domain walls exhibit pronounced curvature, accompanied by an increase in both domain wall and junction density. This transformation is attributed to the pronounced influence of kinks, inducing sample warping, where “dipole–dipole” interactions are dominant (d−2). Moreover, a critical thickness range that delineates a crossover between the monopolar and dipolar regimens is experimentally identified and corroborated by atomic simulations. These findings are relevant for in situ TEM studies and for the development of novel devices based on free-standing ferroic thin films and nanomaterials.

AB - The elastic interaction between kinks (and antikinks) within domain walls plays a pivotal role in shaping the domain structure, and their dynamics. In bulk materials, kinks interact as elastic monopoles, dependent on the distance between walls (d−1) and typically characterized by a rigid and straight domain configuration. In this work the evolution of the domain structure is investigated, as the sample size decreases, by the means of in situ heating microscopy techniques on free-standing samples. As the sample size decreases, a significant transformation is observed: domain walls exhibit pronounced curvature, accompanied by an increase in both domain wall and junction density. This transformation is attributed to the pronounced influence of kinks, inducing sample warping, where “dipole–dipole” interactions are dominant (d−2). Moreover, a critical thickness range that delineates a crossover between the monopolar and dipolar regimens is experimentally identified and corroborated by atomic simulations. These findings are relevant for in situ TEM studies and for the development of novel devices based on free-standing ferroic thin films and nanomaterials.

KW - domain structure

KW - domain wall curvature

KW - ferroelastics

KW - free‐standing samples

KW - surface relaxation

U2 - 10.1002/smll.202400646

DO - 10.1002/smll.202400646

M3 - Article

SN - 1613-6810

VL - 20

JO - Small

JF - Small

IS - 35

M1 - 2400646

ER -

Evidence of the monopolar‐dipolar crossover regime: a multiscale study of ferroelastic domains by in situ microscopy techniques

Abstract

Bibliographical note

Keywords

Access to Document

Fingerprint

Student theses

Ferroelastic domain dynamics: a multiscale study through in situ microscopy

Cite this