Degeneracies and fluctuations of Néel skyrmions in confined geometries

Keesman, Rick; Leonov, A. O.; Dieten, P. van; Buhrandt, Stefan; Barkema, G. T.; Fritz, Lars; Duine, R. A.

doi:10.1103/physrevb.92.134405

Cited by 45 publications

(52 citation statements)

References 53 publications

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“…In both cases the phase diagram is colored using the density order parameter ρ, but two different scaling schemes have been found to separate the corresponding phases. While in [20,28] no distinction between the Skx and the isolated skyrmions has been made, in our calculations at finite temperatures the isolated skyrmions survive up to the boundary indicated by the stars. The transition from the skyrmion lattice to the spin-spiral state appears to be diffuse: a rather broad region exists in which skyrmions and elongated spiral-like textures coexist as can also be observed in figure 1(a).…”

Section: Phase Diagrammentioning

confidence: 61%

Minimal radius of magnetic skyrmions: statics and dynamics

et al. 2016

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In a broad range of applied magnetic fields and material parameters isolated magnetic skyrmions condense into skyrmion lattices. While the geometry of isolated skyrmions and their lattice counterparts strongly depend on field and Dzyaloshinski-Moriya interaction, this issue has not been adequately addressed in previous studies. Meanwhile, this information is extremely important for applications, because the skyrmion size and the interskyrmion distance have to be tuned for skyrmion based memory and logic devices. In this investigation we elucidate the size and density-dependent phase diagram showing traditional phases in field versus material parameters space by means of Monte-Carlo simulations on a discrete lattice. The obtained diagram permits us to establish that, in contrast to the continuum limit, skyrmions on a discrete lattice cannot be smaller than some critical size and have a very specific shape. These minimal skyrmions correspond to the micromagnetic configuration at the energy barrier between the ferromagnetic and the skyrmionic states. Furthermore, we use atomistic Landau-Lifshitz-Gilbert simulations to study dynamics of the skyrmion annihilation. It is shown that this procees consists of two stages: the continuous skyrmion contraction and its discontinuous annihilation. The detailed analysis of this dynamical process is given.

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Section: Phase Diagrammentioning

confidence: 61%

Minimal radius of magnetic skyrmions: statics and dynamics

et al. 2016

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“…The topological charge is also no longer an integer for free boundaries, which complicates the determination of the skyrmion lifetime at finite temperature. Therefore, we conclude that the periodic boundary conditions are probably more appropriate for the simulation of a homogeneous system considered in this paper, while free boundary conditions are preferable in constrained geometries [74,75]. siderations given in Appendix C. Even if such structures with opposite topological charge would form in the system, we expect that the energy barrier between the fieldpolarized state and the skyrmion will mainly depend on the isotropic exchange interactions in the system [22,52], which makes no difference between skyrmions and antiskyrmions with opposite topological charges.…”

Section: Appendix D: the Effect Of Periodic Boundary Conditionsmentioning

confidence: 99%

“…Ref. [74]. The topological charge is also no longer an integer for free boundaries, which complicates the determination of the skyrmion lifetime at finite temperature.…”

Section: Appendix D: the Effect Of Periodic Boundary Conditionsmentioning

confidence: 99%

Complex magnetic phase diagram and skyrmion lifetime in an ultrathin film from atomistic simulations

Rózsa¹,

Simon²,

Palotás³

et al. 2016

Phys. Rev. B

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We determined the magnetic B − T phase diagram of PdFe bilayer on Ir(111) surface by performing Monte Carlo and spin dynamics simulations based on an effective classical spin model. The parameters of the spin model were determined by ab initio methods. At low temperatures we found three types of ordered phases, while at higher temperatures, below the completely disordered paramagnetic phase, a large region of the phase diagram is associated with a fluctuation-disordered phase. Within the applied model, this state is characterized by the presence of skyrmions with finite lifetime. According to the simulations, this lifetime follows the Arrhenius law as a function of temperature.

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“…Importantly, magnetic saturation is never fully reached in confined nanosystems as surface modulations occur near the sample edges (so called chiral surface twists) 13 with a penetration depth estimated as 0.1 p (p is the helix period at zero field) 14 . In the case of a narrow strip, the edge states manifest themselves as remnants of the helical spiral [14][15][16] with a smooth deviation of the magnetization from being co-aligned with the field in the middle of the sample ( Fig. 1 (a), (b)) to composing some (field-and anisotropy-dependent) angle θ 0 at the edge.…”

mentioning

confidence: 99%

“…In the saturated state, isolated skyrmions are axisymmetric and translationally invariant along z 1,2 . Chiral surface twists for H > H D have been investigated in a number of earlier contributions [14][15][16] . Below H D , the incompatibility with the longitudially modulated conical phase imposes a complex, three-dimensional character on the magnetic modulations of the skyrmions and edge states (Figs.…”

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confidence: 99%

Spintronics via non-axisymmetric chiral skyrmions

Leonov

Loudon²,

Bogdanov

2016

Applied Physics Letters

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Micromagnetic calculations demonstrate a peculiar evolution of non-axisymmetric skyrmions driven by an applied magnetic field in confined helimagnets with longitudinal modulations. We argue that these specific solitonic states can be employed in nanoelectronic devices as an effective alternative to the common axisymmetric skyrmions which occur in magnetically saturated states.PACS numbers: 75.30. Kz, 12.39.Dc, Two-dimensional topological solitons with an axisymmetric structure (commonly addressed as isolated chiral skyrmions 1 ) are stabilized by Dzyaloshinskii-Moriya interactions in the saturated states of noncentrosymmetric magnetic materials 2 . In magnetic nanolayers, chiral skyrmions represent nanosized spots of reverse magnetization which can be created or deleted by a magnetic tip 3 and moved by electric currents and applied magnetic fields 1,3,4 . Due to their remarkable properties, magnetic skyrmions are considered promising objects for next-generation memory and logic devices 5-7 , which store information in the form of skyrmions that can be manipulated at room temperature [8][9][10] . In practice, isolated magnetic skyrmions are induced and manipulated in laterally confined saturated helimagnets (slabs, narrow strips, nanowires, and nanodots) 1,3,7,11,12 . Importantly, magnetic saturation is never fully reached in confined nanosystems as surface modulations occur near the sample edges (so called chiral surface twists)13 with a penetration depth estimated as 0.1 p (p is the helix period at zero field)14 . In the case of a narrow strip, the edge states manifest themselves as remnants of the helical spiral 14-16 with a smooth deviation of the magnetization from being co-aligned with the field in the middle of the sample ( Fig. 1 (a), (b)) to composing some (field-and anisotropy-dependent) angle θ 0 at the edge. To date, theoretical investigations of confined chiral skyrmions and their applications have been restricted to saturated helimagnets ( Fig. 1(b)) 6,17 . In that case, the skyrmion-edge interaction has a repulsive character (Eq. (21) in Ref. 14) due to the same rotational sense of the magnetization in the axisymmetric skyrmions and the surface modulations.In this Letter we address a special type of nonaxisymmetric skyrmion introduced in Ref. 18. These three-dimensional solitonic states arise in longitudinally modulated chiral ferromagnets (with the conical phase, Fig. 1 (c)) and hence are inhomogeneous along their axes. Within the micromagnetic model we calculate the structure of non-axisymmetric skyrmions and edge modulations in a confined chiral helimagnet. We show that the conical phase turns the skyrmion-edge repulsion into an attraction and consequently, there is an equilibrium distance from the edge at which the force on the skyrmions is zero. This equilibrium distance can be tuned by changing the applied magnetic field and it acts to guide the skyrmions along the edges. We demonstrate that specific properties of confined non-axisymmetric skyrmions offer new directions in spintronic applicat...

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Degeneracies and fluctuations of Néel skyrmions in confined geometries

Cited by 45 publications

References 53 publications

Minimal radius of magnetic skyrmions: statics and dynamics

Minimal radius of magnetic skyrmions: statics and dynamics

Complex magnetic phase diagram and skyrmion lifetime in an ultrathin film from atomistic simulations

Spintronics via non-axisymmetric chiral skyrmions

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