Please use this identifier to cite or link to this item: https://doi.org/10.1038/s41586-021-03219-6
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dc.titleAntiferromagnetic half-skyrmions and bimerons at room temperature
dc.contributor.authorHariom Jani
dc.contributor.authorJheng-Cyuan Lin
dc.contributor.authorJiahao Chen
dc.contributor.authorJack Harrison
dc.contributor.authorFrancesco Maccherozzi
dc.contributor.authorJonathon Schad
dc.contributor.authorSaurav Prakash
dc.contributor.authorChang-Beom Eom
dc.contributor.authorA. Ariando
dc.contributor.authorT. Venkatesan
dc.contributor.authorPaolo G. Radaelli
dc.date.accessioned2021-04-13T09:30:49Z
dc.date.available2021-04-13T09:30:49Z
dc.date.issued2021-02-03
dc.identifier.citationHariom Jani, Jheng-Cyuan Lin, Jiahao Chen, Jack Harrison, Francesco Maccherozzi, Jonathon Schad, Saurav Prakash, Chang-Beom Eom, A. Ariando, T. Venkatesan, Paolo G. Radaelli (2021-02-03). Antiferromagnetic half-skyrmions and bimerons at room temperature. Nature 590 : 74 - 79. ScholarBank@NUS Repository. https://doi.org/10.1038/s41586-021-03219-6
dc.identifier.issn14764687
dc.identifier.urihttps://scholarbank.nus.edu.sg/handle/10635/189220
dc.description.abstractIn the quest for post-CMOS (complementary metal–oxide–semiconductor) technologies, driven by the need for improved efficiency and performance, topologically protected ferromagnetic ‘whirls’ such as skyrmions1,2,3,4,5,6,7,8 and their anti-particles have shown great promise as solitonic information carriers in racetrack memory-in-logic or neuromorphic devices1,9,10,11. However, the presence of dipolar fields in ferromagnets, which restricts the formation of ultrasmall topological textures3,6,8,9,12, and the deleterious skyrmion Hall effect, when skyrmions are driven by spin torques9,10,12, have thus far inhibited their practical implementation. Antiferromagnetic analogues, which are predicted to demonstrate relativistic dynamics, fast deflection-free motion and size scaling, have recently become the subject of intense focus9,13,14,15,16,17,18,19, but they have yet to be experimentally demonstrated in natural antiferromagnetic systems. Here we realize a family of topological antiferromagnetic spin textures in α-Fe2O3—an Earth-abundant oxide insulator—capped with a platinum overlayer. By exploiting a first-order analogue of the Kibble–Zurek mechanism20,21, we stabilize exotic merons and antimerons (half-skyrmions)8 and their pairs (bimerons)16,22, which can be erased by magnetic fields and regenerated by temperature cycling. These structures have characteristic sizes of the order of 100 nanometres and can be chemically controlled via precise tuning of the exchange and anisotropy, with pathways through which further scaling may be achieved. Driven by current-based spin torques from the heavy-metal overlayer, some of these antiferromagnetic textures could emerge as prime candidates for low-energy antiferromagnetic spintronics at room temperature1,9,10,11,23.
dc.publisherNature Research
dc.subjectFerromagnetism
dc.subjectMagnetic properties and materials
dc.subjectPhase transitions and critical phenomena
dc.subjectSpintronics
dc.subjectSurfaces
dc.subjectinterfaces and thin films
dc.typeArticle
dc.contributor.departmentELECTRICAL AND COMPUTER ENGINEERING
dc.contributor.departmentPHYSICS
dc.contributor.departmentNUS NANOSCIENCE & NANOTECH INITIATIVE
dc.description.doi10.1038/s41586-021-03219-6
dc.description.sourcetitleNature
dc.description.volume590
dc.description.page74 - 79
dc.published.statePublished
dc.grant.idNRF2015NRF-CRP001-015
dc.grant.fundingagencyNational Research Foundation
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