Stabilizing spin spirals and isolated skyrmions at low magnetic field exploiting vanishing magnetic anisotropy

Hervé, Marie; Dupé, Bertrand; Lopes, Rafael; Böttcher, Marie; Martins, Maximiliano; Balashov, T.; Gerhard, Lukas; Sinova, Jairo; Wulfhekel, Wulf

doi:10.1038/s41467-018-03240-w

Cited by 99 publications

(105 citation statements)

References 52 publications

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“…The easy-plane anisotropy for LSMO films has been found to be AS 2 ≈0.21 meV [46] which gives A≈0.09 meV with S=3/2. Therefore, the critical DM interaction strength to realize the skyrmion crystal D c ∼ √ JA [47][48][49] appears in a range 0.3meV D c 0.6 meV. LSMO also has a weak antiferromagnetic coupling [34] which has not been included in our description.…”

Section: Discussionmentioning

confidence: 99%

Topological Hall effect and emergent skyrmion crystal at manganite-iridate oxide interfaces

2019

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Scalar spin chirality is expected to induce a finite contribution to the Hall response at low temperatures. We study this spin-chirality-driven Hall effect, known as the topological Hall effect, at the manganite side of the interface between La1−xSrxMnO3 and SrIrO3. The ferromagnetic doubleexchange hopping at the manganite layer, in conjunction with the Dzyaloshinskii-Moriya (DM) interaction which arises at the interface due to broken inversion symmetry and strong spin-orbit coupling from the iridate layer, could produce a skyrmion-crystal (SkX) phase in the presence of an external magnetic field. Using the Monte Carlo technique and a two-orbital spin-fermion model for manganites, supplemented by an in-plane DM interaction, we obtain phase diagrams which reveal at low temperatures a clear SkX phase and also a low-field spin-spiral phase. Increasing temperature, a skyrmion-gas phase, precursor of the SkX phase upon cooling, was identified. The topological Hall effect primarily appears in the SkX phase, as observed before in oxide heterostructures. We conclude that the manganite-iridate superlattices provide another useful platform to explore a plethora of unconventional magnetic and transport properties. arXiv:1905.09887v2 [cond-mat.str-el]

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Section: Discussionmentioning

confidence: 99%

Topological Hall effect and emergent skyrmion crystal at manganite-iridate oxide interfaces

2019

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“…The supercurrent that emerges as a consequence of a domain wall in a superconductor-ferromagnet bilayer (we may view skyrmions as a limiting case of general domain wall structures in this regard by continuously shrinking a circular domain to a skyrmion core) will be bounded by J max = cM (d F /δ) [73], where c is the speed of light, M the saturation magnetization, d F the thickness of the magnetic layer, and δ the width of the domain wall (here: related to the skyrmion radius). As we focus on d F δ, where d F may correspond to monoatomic layer thickness [48] whereas δ will be on the order of 10 -100 nanometers, we can expect that J max is insignificant in the thin-film limit. In this limit, vortices may not form spontaneously, but can still be induced by an external out-of-plane magnetic field [67].…”

Section: Majorana Criterion In a Skyrmion-vortex Pairmentioning

confidence: 99%

“…The idea of having an MBS captured inside a skyrmion is very appealing, because the existing tools for skyrmion manipulation could potentially be employed to navigate single Majorana modes. It is particularly note-worthy that a recent experiment [48] has demonstrated the possibility to move individual skyrmions in the plane with a scanning tunneling microscope tip. In that way, one could envision explicit real-space braiding operations with MBS.…”

Section: Introductionmentioning

confidence: 99%

Majorana bound states in magnetic skyrmions imposed onto a superconductor

2019

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We consider a superconducting film exchange-coupled to a close-by chiral magnetic layer and study how magnetic skyrmions can induce the formation of Majorana bound states (MBS) in the superconductor. Inspired by a proposal by Yang et al. [Phys. Rev. B 93, 224505 (2016)], which suggested MBS in skyrmions of even winding number, we explore whether such skyrmions could result from a merger of ordinary skyrmions. We conclude that the formation of higher-winding skyrmions is not realistic in chiral magnets. Subsequently, we present a possibility to obtain MBS from realistic skyrmions of winding number one, if a skyrmion-vortex pair is formed instead of a bare skyrmion. Specifically, we show that MBS are supported in a pair of a circular skyrmion and a vortex which both have a winding number of one. We back up our analytical prediction with results from numerical diagonalization and obtain the spatial profile of the MBS. In light of recent experimental progress on the manipulation of skyrmions, such systems are promising candidates to achieve direct spatial control of MBS. arXiv:1904.04177v2 [cond-mat.supr-con]

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“…Skyrmions are also present in Fe (ultra-)thin-films, e.g., Fe monolayer on Ir(111) [20], Pd/Fe bilayer on Ir(111) [9,10,[30][31][32], 3 monolayers of Fe on Ir(111) [33] and Co ultrathin film Co/Ru(0001) [34]. In that case, magnetic interactions can be tuned by the choice of the magnetic film [35,36], the hybridization with the different substrates [11,35,37,38], or optional overlayers [9].…”

Section: Introductionmentioning

confidence: 99%

B–T phase diagram of Pd/Fe/Ir(111) computed with parallel tempering Monte Carlo

et al. 2018

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We use an atomistic spin model derived from density functional theory calculations for the ultra-thin film Pd/Fe/Ir(111) to show that temperature induces coexisting non-zero skyrmion and antiskyrmion densities. We apply the parallel tempering Monte Carlo method in order to reliably compute thermodynamical quantities and the B-T phase diagram in the presence of frustrated exchange interactions. We evaluate the critical temperatures using the topological susceptibility. We show that the critical temperatures depend on the magnetic field in contrast to previous work. In total, we identify five phases: spin spiral, skyrmion lattice, ferromagnetic phase, intermediate region with finite topological charge and paramagnetic phase. To explore the effect of frustrated exchange interactions, we calculate the B-T phase diagram, when only effective exchange parameters are taken into account.

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Stabilizing spin spirals and isolated skyrmions at low magnetic field exploiting vanishing magnetic anisotropy

Cited by 99 publications

References 52 publications

Topological Hall effect and emergent skyrmion crystal at manganite-iridate oxide interfaces

Topological Hall effect and emergent skyrmion crystal at manganite-iridate oxide interfaces

Majorana bound states in magnetic skyrmions imposed onto a superconductor

B–T phase diagram of Pd/Fe/Ir(111) computed with parallel tempering Monte Carlo

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