2020
DOI: 10.1038/s41586-019-1845-4
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Inverse transition of labyrinthine domain patterns in ferroelectric thin films

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Cited by 95 publications
(67 citation statements)
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“…[ 58 ] Direct evidence for the formation of rotating polarization at atomic scale was made in 2011 when experimentalists were able to directly observe continuous polarization rotation near the interfaces of ferroelectric thin films using aberration‐corrected (scanning) transmission electron microscopy (TEM). [ 59,60 ] Since then, several exotic polar topologies such as flux‐closure domains, [ 61–65 ] vortices, [ 66–71 ] non‐Ising‐like domain walls, [ 72–74 ] center‐type domains, [ 68,70,75,76 ] labyrinthine domains, [ 77 ] bubbles, [ 78 ] incommensurate curl domains, [ 79 ] spiral states, [ 80 ] hedgehog states, [ 81 ] and polar skyrmions, [ 82,83 ] have been revealed in various ferroelectric materials. Which kind of polar topology develops would depend on the relative magnitudes of various energies, such as elastic (i.e., strain), electrostatic (i.e., depolarization), polarization/chemical gradient, and interfacial coupling energies.…”
Section: Introductionmentioning
confidence: 99%
“…[ 58 ] Direct evidence for the formation of rotating polarization at atomic scale was made in 2011 when experimentalists were able to directly observe continuous polarization rotation near the interfaces of ferroelectric thin films using aberration‐corrected (scanning) transmission electron microscopy (TEM). [ 59,60 ] Since then, several exotic polar topologies such as flux‐closure domains, [ 61–65 ] vortices, [ 66–71 ] non‐Ising‐like domain walls, [ 72–74 ] center‐type domains, [ 68,70,75,76 ] labyrinthine domains, [ 77 ] bubbles, [ 78 ] incommensurate curl domains, [ 79 ] spiral states, [ 80 ] hedgehog states, [ 81 ] and polar skyrmions, [ 82,83 ] have been revealed in various ferroelectric materials. Which kind of polar topology develops would depend on the relative magnitudes of various energies, such as elastic (i.e., strain), electrostatic (i.e., depolarization), polarization/chemical gradient, and interfacial coupling energies.…”
Section: Introductionmentioning
confidence: 99%
“…Understanding the intricate formation processes at play in the formation of modulated phases is thus pivotal for the development of future technologies, e.g., domain wall nanoelectronics [4][5][6][7][8][9][10][11][12][13][14][15][16][17][18][19][20]21,22 , a field of research that has recently seen fiery surge of interest. So far, modulated phases of ferroelectric domains such as the dipolar maze or labyrinthine phase 23 , and the nano-bubble or skyrmionic phase 21,22,24 have been somewhat regarded as conceptually disparate [24][25][26][27][28][29][30] . We here numerically predict and experimentally evidence that, depending on the magnitude of the external field, temperature and the kinetics of the phase separation, topologically non-trivial phases emerge upon sub-critically quenching tetragonal Pb(Zr x Ti 1 − x )O 3 through either spinodal decomposition or nucleation processes.…”
mentioning
confidence: 99%
“…We were motivated to explore this by a recent work from Nahas et al in which a labyrinthine mosaic domain pattern (disordered stripe domains with topological defects) of ferroelectric domains in BFO films could be converted to a perfectly ordered stripe domain pattern with lengths of over several tens of microns. [ 59 ] Such changes were experimentally obtained by an ex situ annealing process whereby the sample was held at 1073 K for 1 h under oxygen flow and cooled down slowly to room temperature (2 K min −1 ).…”
Section: Resultsmentioning
confidence: 99%