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Field-induced double spin spiral in a frustrated chiral magnet

Type of publication Peer-reviewed
Publikationsform Original article (peer-reviewed)
Author Ramakrishnan Mahesh, Constable Evan, Cano Andres, Mostovoy Maxim, White Jonathan S., Gurung Namrata, Schierle Enrico, Brion Sophie de, Colin Claire V., Gay Frederic, Lejay Pascal, Ressouche Eric, Weschke Eugen, Scagnoli Valerio, Ballou Rafik, Simonet Virginie, Staub Urs,
Project Discovery and Nanoengineering of Novel Skyrmion-hosting Materials
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Original article (peer-reviewed)

Journal npj Quantum Materials
Volume (Issue) 4(1)
Page(s) 60 - 60
Title of proceedings npj Quantum Materials
DOI 10.1038/s41535-019-0199-3

Open Access

URL http://doi.org/10.1038/s41535-019-0199-3
Type of Open Access Publisher (Gold Open Access)

Abstract

Abstract Magnetic ground states with peculiar spin textures, such as magnetic skyrmions and multifunctional domains are of enormous interest for the fundamental physics governing their origin as well as potential applications in emerging technologies. Of particular interest are multiferroics, where sophisticated interactions between electric and magnetic phenomena can be used to tailor several functionalities. We report the direct observation of a magnetic field induced long-wavelength spin spiral modulation in the chiral compound Ba $${}_{3}$$3 TaFe $${}_{3}$$3 Si $${}_{2}$$2 O $${}_{14}$$14 , which emerges out of a helical ground state, and is hallmarked by the onset of a unique chirality-dependent contribution to the bulk electric polarization. The periodicity of the field-induced modulation, several hundreds of nm depending on the field value, is comparable to the length scales of mesoscopic topological defects such as skyrmions, merons, and solitons. The phase transition and observed threshold behavior are consistent with a phenomenology based on the allowed Lifshitz invariants for the chiral symmetry of langasite, which intriguingly contain all the essential ingredients for the realization of topologically stable antiferromagnetic skyrmions. Our findings open up new directions to explore topological correlations of antiferromagnetic spintronic systems based on non-collinear magnetic systems with additional ferroic functionalities.
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