Flicker vortex structures in multiferroic materials

Z. Zhao; X. Ding; E. K.H. Salje

doi:10.1063/1.4896143

Flicker vortex structures in multiferroic materials

Z. Zhao
, X. Ding
, E. K.H. Salje

School of Materials Science and Engineering

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

21 Scopus citations

Abstract

Computer simulation of ferroelastic materials reveals dynamic polar vortex structures related to flexo-electricity between cation and anion lattices. At finite temperatures, the vortices are found to flicker in time and space. Widely spaced ferroelastic twin boundaries nucleate vortices while dense twin boundaries suppress them. The time averaged number of vortices at any site decays exponentially, indicating the highly mobile dynamics of the vortex lattice. Applied electric fields break the rotational symmetry of vortices and finally destroy them. The total number density of vortices follows a field and temperature dependence as N(E)=N0/[1+Aexp(E/k(T-TVF))] with T_VF<0. The observed vortex structures are akin to those observed in magnetic and superconducting disordered vortex lattices.

Original language	English
Article number	112906
Journal	Applied Physics Letters
Volume	105
Issue number	11
DOIs	https://doi.org/10.1063/1.4896143
State	Published - 15 Sep 2014

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title = "Flicker vortex structures in multiferroic materials",

abstract = "Computer simulation of ferroelastic materials reveals dynamic polar vortex structures related to flexo-electricity between cation and anion lattices. At finite temperatures, the vortices are found to flicker in time and space. Widely spaced ferroelastic twin boundaries nucleate vortices while dense twin boundaries suppress them. The time averaged number of vortices at any site decays exponentially, indicating the highly mobile dynamics of the vortex lattice. Applied electric fields break the rotational symmetry of vortices and finally destroy them. The total number density of vortices follows a field and temperature dependence as N(E)=N0/[1+Aexp(E/k(T-TVF))] with TVF<0. The observed vortex structures are akin to those observed in magnetic and superconducting disordered vortex lattices.",

author = "Z. Zhao and X. Ding and Salje, \{E. K.H.\}",

note = "Publisher Copyright: {\textcopyright} 2014 AIP Publishing LLC.",

year = "2014",

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doi = "10.1063/1.4896143",

language = "英语",

volume = "105",

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T1 - Flicker vortex structures in multiferroic materials

AU - Zhao, Z.

AU - Ding, X.

AU - Salje, E. K.H.

PY - 2014/9/15

Y1 - 2014/9/15

N2 - Computer simulation of ferroelastic materials reveals dynamic polar vortex structures related to flexo-electricity between cation and anion lattices. At finite temperatures, the vortices are found to flicker in time and space. Widely spaced ferroelastic twin boundaries nucleate vortices while dense twin boundaries suppress them. The time averaged number of vortices at any site decays exponentially, indicating the highly mobile dynamics of the vortex lattice. Applied electric fields break the rotational symmetry of vortices and finally destroy them. The total number density of vortices follows a field and temperature dependence as N(E)=N0/[1+Aexp(E/k(T-TVF))] with TVF<0. The observed vortex structures are akin to those observed in magnetic and superconducting disordered vortex lattices.

AB - Computer simulation of ferroelastic materials reveals dynamic polar vortex structures related to flexo-electricity between cation and anion lattices. At finite temperatures, the vortices are found to flicker in time and space. Widely spaced ferroelastic twin boundaries nucleate vortices while dense twin boundaries suppress them. The time averaged number of vortices at any site decays exponentially, indicating the highly mobile dynamics of the vortex lattice. Applied electric fields break the rotational symmetry of vortices and finally destroy them. The total number density of vortices follows a field and temperature dependence as N(E)=N0/[1+Aexp(E/k(T-TVF))] with TVF<0. The observed vortex structures are akin to those observed in magnetic and superconducting disordered vortex lattices.

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DO - 10.1063/1.4896143

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SN - 0003-6951

VL - 105

JO - Applied Physics Letters

JF - Applied Physics Letters

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ER -

Flicker vortex structures in multiferroic materials

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