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. 2021 Feb;20(2):194-201.
doi: 10.1038/s41563-020-00818-y. Epub 2020 Oct 12.

Local negative permittivity and topological phase transition in polar skyrmions

S Das #  1   2 Z Hong #  3   4 V A Stoica #  3 M A P Gonçalves #  5   6   7 Y T Shao  8 E Parsonnet  9 E J Marksz  10 S Saremi  11 M R McCarter  9 A Reynoso  9 C J Long  10 A M Hagerstrom  10 D Meyers  11 V Ravi  11 B Prasad  11 H Zhou  12 Z Zhang  12 H Wen  12 F Gómez-Ortiz  6 P García-Fernández  6 J Bokor  13 J Íñiguez  5   7 J W Freeland  12 N D Orloff  10 J Junquera  6 L Q Chen  3 S Salahuddin  13 D A Muller  8   14 L W Martin  11   15 R Ramesh  16   17   18
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Free article

Local negative permittivity and topological phase transition in polar skyrmions

S Das et al. Nat Mater. 2021 Feb.
Free article

Erratum in

  • Author Correction: Local negative permittivity and topological phase transition in polar skyrmions.
    Das S, Hong Z, Stoica VA, Gonçalves MAP, Shao YT, Parsonnet E, Marksz EJ, Saremi S, McCarter MR, Reynoso A, Long CJ, Hagerstrom AM, Meyers D, Ravi V, Prasad B, Zhou H, Zhang Z, Wen H, Gómez-Ortiz F, García-Fernández P, Bokor J, Íñiguez J, Freeland JW, Orloff ND, Junquera J, Chen LQ, Salahuddin S, Muller DA, Martin LW, Ramesh R. Das S, et al. Nat Mater. 2021 Jun;20(6):905. doi: 10.1038/s41563-021-00962-z. Nat Mater. 2021. PMID: 33627832 No abstract available.

Abstract

Topological solitons such as magnetic skyrmions have drawn attention as stable quasi-particle-like objects. The recent discovery of polar vortices and skyrmions in ferroelectric oxide superlattices has opened up new vistas to explore topology, emergent phenomena and approaches for manipulating such features with electric fields. Using macroscopic dielectric measurements, coupled with direct scanning convergent beam electron diffraction imaging on the atomic scale, theoretical phase-field simulations and second-principles calculations, we demonstrate that polar skyrmions in (PbTiO3)n/(SrTiO3)n superlattices are distinguished by a sheath of negative permittivity at the periphery of each skyrmion. This enhances the effective dielectric permittivity compared with the individual SrTiO3 and PbTiO3 layers. Moreover, the response of these topologically protected structures to electric field and temperature shows a reversible phase transition from the skyrmion state to a trivial uniform ferroelectric state, accompanied by large tunability of the dielectric permittivity. Pulsed switching measurements show a time-dependent evolution and recovery of the skyrmion state (and macroscopic dielectric response). The interrelationship between topological and dielectric properties presents an opportunity to simultaneously manipulate both by a single, and easily controlled, stimulus, the applied electric field.

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