Ivana Levatić scite author profile

Small-angle neutron scattering has been employed to study the influence of applied electric (E-)fields on the skyrmion lattice in the chiral lattice magnetoelectric Cu(2)OSeO(3). Using an experimental geometry with the E-field parallel to the [111] axis, and the magnetic field parallel to the [11(-)0] axis, we demonstrate that the effect of applying an E-field is to controllably rotate the skyrmion lattice around the magnetic field axis. Our results are an important first demonstration for a microscopic coupling between applied E-fields and the skyrmions in an insulator, and show that the general emergent properties of skyrmions may be tailored according to the properties of the host system.

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Dissipation processes in the insulating skyrmion compoundCu2OSeO3

Levatić

Šurija

Berger

et al. 2014

Phys. Rev. B

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We present a detailed study of the phase diagram surrounding the skyrmion lattice (SkL) phase of Cu 2 OSe 2 O 3 using high-precision magnetic ac susceptibility measurements. An extensive investigation of transition dynamics around the SkL phase using the imaginary component of the susceptibility revealed that at the conical-to-SkL transition a broad dissipation region exists with a complex frequency dependence. The analysis of the observed behavior within the SkL phase indicates a distribution of relaxation times intrinsically related to SkL. At the SkL-to-paramagnet transition a narrow first-order peak is found that exhibits a strong frequency and magnetic field dependence. Surprisingly, very similar dependence has been discovered for the first-order transition below the SkL phase, i.e. where the system enters the helical and conical state(s), indicating similar processes across the order-disorder transition.

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Dramatic pressure-driven enhancement of bulk skyrmion stability

Levatić

Popčević

Šurija

et al. 2016

Sci Rep

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The recent discovery of magnetic skyrmion lattices initiated a surge of interest in the scientific community. Several novel phenomena have been shown to emerge from the interaction of conducting electrons with the skyrmion lattice, such as a topological Hall-effect and a spin-transfer torque at ultra-low current densities. In the insulating compound Cu2OSeO3, magneto-electric coupling enables control of the skyrmion lattice via electric fields, promising a dissipation-less route towards novel spintronic devices. One of the outstanding fundamental issues is related to the thermodynamic stability of the skyrmion lattice. To date, the skyrmion lattice in bulk materials has been found only in a narrow temperature region just below the order-disorder transition. If this narrow stability is unavoidable, it would severely limit applications. Here we present the discovery that applying just moderate pressure on Cu2OSeO3 substantially increases the absolute size of the skyrmion pocket. This insight demonstrates directly that tuning the electronic structure can lead to a significant enhancement of the skyrmion lattice stability. We interpret the discovery by extending the previously employed Ginzburg-Landau approach and conclude that change in the anisotropy is the main driver for control of the size of the skyrmion pocket.

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Magnetic dynamics across the in-field transition in Ca3Co2O6

et al. 2020

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Ivana Levatić

Electric field control of the skyrmion lattice in Cu₂OSeO₃

Dissipation processes in the insulating skyrmion compoundCu2OSeO3

Dramatic pressure-driven enhancement of bulk skyrmion stability

Magnetic dynamics across the in-field transition in Ca3Co2O6

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Ivana Levatić

Electric field control of the skyrmion lattice in Cu2OSeO3

Dissipation processes in the insulating skyrmion compoundCu2OSeO3

Dramatic pressure-driven enhancement of bulk skyrmion stability

Magnetic dynamics across the in-field transition in Ca3Co2O6

Contact Info

Product

Resources

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Electric field control of the skyrmion lattice in Cu₂OSeO₃