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RESEARCH PRODUCT
Skyrmion formation due to unconventional magnetic modes in anisotropic multiband superconductors
Mikhail SilaevThomas WinyardThomas WinyardEgor Babaevsubject
SuperconductivityPhysicsta114SkyrmionCondensed Matter - SuperconductivitysuperconductivityDegrees of freedommultiband superconductivityFOS: Physical sciencesvortices in superconductors02 engineering and technology021001 nanoscience & nanotechnology01 natural sciencessuprajohteetSuperconductivity (cond-mat.supr-con)Theoretical physicsCondensed Matter::Superconductivity0103 physical sciencesTopological invariants010306 general physics0210 nano-technologyAnisotropydescription
Multiband superconductors have a sufficient number of degrees of freedom to allow topological excitations characterized by Skyrmionic topological invariants. In the most common, clean s-wave multiband, systems the interband magnetic coupling favours composite vortex solutions, without a Skyrmionic topological charge. It was discussed recently that certain kinds of anisotropies lead to hybridisation of the interband phase difference (Leggett) mode with magnetic modes, dramatically changing the hydromagnetostatics of the system. Here we report this effect for a range of parameters that substantially alter the nature of the topological excitations, leading to solutions characterized by a nontrivial topological invariant, rather than the standard composite vortex solutions. This invariant is not truly topologically conserved but is energetically conserved, leading to a texture formed of bound excitations in each band, namely fractional vortices, each carrying a fraction of the flux quantum. We demonstrate that in this regime there is a rich spectrum of Skyrmion solutions, with various topological charges, that are robust with respect to changes of parameters of the system and present for a wide range of anisotropies.
| year | journal | country | edition | language |
|---|---|---|---|---|
| 2018-01-31 | Physical Review B |