Excess of topological defects induced by confinement in vortex nanocrystals

N. R.Cejas Bolecek; M. I. Dolz; H. Pastoriza; M. Konczykowski; C. J. Van Der Beek; A. B. Kolton; Y. Fasano

doi:10.1103/PhysRevB.96.024507

Excess of topological defects induced by confinement in vortex nanocrystals

N. R.Cejas Bolecek
, M. I. Dolz
, H. Pastoriza
, M. Konczykowski
, C. J. Van Der Beek
, A. B. Kolton
, Y. Fasano

Instituto Balseiro
IMASL-CONICET/Universidad Nacional De San Luis
Université Paris-Saclay

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

Abstract

We directly image individual vortex positions in nanocrystals in order to unveil the structural property that contributes to the depletion of the entropy jump entailed at the first-order transition. On reducing the nanocrystal size, the density of topological defects increases near the edges over a characteristic length. Within this "healing-length" distance from the sample edge, vortex rows tend to bend, while towards the center of the sample, the positional order of the vortex structure is what is expected for the Bragg-glass phase. This suggests that the healing length may be a key quantity to model confinement effects in the first-order transition of extremely layered vortex nanocrystals.

Original language	English
Article number	024507
Journal	Physical Review B
Volume	96
Issue number	2
DOIs	https://doi.org/10.1103/PhysRevB.96.024507
Publication status	Published - 14 Jul 2017
Externally published	Yes

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10.1103/PhysRevB.96.024507

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title = "Excess of topological defects induced by confinement in vortex nanocrystals",

abstract = "We directly image individual vortex positions in nanocrystals in order to unveil the structural property that contributes to the depletion of the entropy jump entailed at the first-order transition. On reducing the nanocrystal size, the density of topological defects increases near the edges over a characteristic length. Within this {"}healing-length{"} distance from the sample edge, vortex rows tend to bend, while towards the center of the sample, the positional order of the vortex structure is what is expected for the Bragg-glass phase. This suggests that the healing length may be a key quantity to model confinement effects in the first-order transition of extremely layered vortex nanocrystals.",

author = "Bolecek, \{N. R.Cejas\} and Dolz, \{M. I.\} and H. Pastoriza and M. Konczykowski and \{Van Der Beek\}, \{C. J.\} and Kolton, \{A. B.\} and Y. Fasano",

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AU - Bolecek, N. R.Cejas

AU - Dolz, M. I.

AU - Pastoriza, H.

AU - Konczykowski, M.

AU - Van Der Beek, C. J.

AU - Kolton, A. B.

AU - Fasano, Y.

PY - 2017/7/14

Y1 - 2017/7/14

N2 - We directly image individual vortex positions in nanocrystals in order to unveil the structural property that contributes to the depletion of the entropy jump entailed at the first-order transition. On reducing the nanocrystal size, the density of topological defects increases near the edges over a characteristic length. Within this "healing-length" distance from the sample edge, vortex rows tend to bend, while towards the center of the sample, the positional order of the vortex structure is what is expected for the Bragg-glass phase. This suggests that the healing length may be a key quantity to model confinement effects in the first-order transition of extremely layered vortex nanocrystals.

AB - We directly image individual vortex positions in nanocrystals in order to unveil the structural property that contributes to the depletion of the entropy jump entailed at the first-order transition. On reducing the nanocrystal size, the density of topological defects increases near the edges over a characteristic length. Within this "healing-length" distance from the sample edge, vortex rows tend to bend, while towards the center of the sample, the positional order of the vortex structure is what is expected for the Bragg-glass phase. This suggests that the healing length may be a key quantity to model confinement effects in the first-order transition of extremely layered vortex nanocrystals.

U2 - 10.1103/PhysRevB.96.024507

DO - 10.1103/PhysRevB.96.024507

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JO - Physical Review B

JF - Physical Review B

IS - 2

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ER -

Excess of topological defects induced by confinement in vortex nanocrystals

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