Magnus-induced ratchet effects for skyrmions interacting with asymmetric substrates

When a particle is driven with an ac force over an asymmetric potential, it can undergo a ratchet effect that produces a net dc motion of the particle. Ratchet effects have been observed in numerous systems such as superconducting vortices on asymmetric pinning substrates. Skyrmions, stable topological spin textures with particle-like properties, have many similarities to vortices but their behavior is strongly influenced by non-disspative effects arising from a Magnus term in their equation of motion. We show using numerical simulations that pronounced ratchet effects can occur for ac driven skyrmions moving over asymmetric quasi-one-dimensional substrates. We find a new type of ratchet effect called a Magnus-induced transverse ratchet that arises when the ac driving force is applied perpendicular rather than parallel to the asymmetry direction of the substrate. This transverse ratchet effect only occurs when the Magnus term is finite, and the threshold ac amplitude needed to induce it decreases as the Magnus term becomes more prominent. Ratcheting skyrmions follow ordered orbits in which the net displacement parallel to the substrate asymmetry direction is quantized. Skyrmion ratchets represent a new ac current-based method for controlling skyrmion positions and motion for spintronic applications.

[1]  J. H. Franken,et al.  Shift registers based on magnetic domain wall ratchets with perpendicularly anisotrpoy , 2012 .

[2]  Y. Tokura,et al.  Observation of Skyrmions in a Multiferroic Material , 2012, Science.

[3]  P. Bak,et al.  One-Dimensional Ising Model and the Complete Devil's Staircase , 1982 .

[4]  Kang L. Wang,et al.  Blowing magnetic skyrmion bubbles , 2015, Science.

[5]  F. Nori,et al.  Superconducting fluxon pumps and lenses , 1999, cond-mat/9910484.

[6]  C. Pfleiderer,et al.  Emergent electrodynamics of skyrmions in a chiral magnet , 2012, Nature Physics.

[7]  D Petit,et al.  Magnetic Domain-Wall Logic , 2005, Science.

[8]  Y. Tokura,et al.  Real-space observation of a two-dimensional skyrmion crystal , 2010, Nature.

[9]  A. Fert,et al.  Skyrmions on the track. , 2013, Nature nanotechnology.

[10]  Y. Tokura,et al.  Topological properties and dynamics of magnetic skyrmions. , 2013, Nature nanotechnology.

[11]  A. Barabasi,et al.  Reducing vortex density in superconductors using the ‘ratchet effect’ , 1999, Nature.

[12]  A. Saxena,et al.  Particle model for skyrmions in metallic chiral magnets: Dynamics, pinning, and creep , 2013, 1302.6205.

[13]  Y. Tokura,et al.  Thermally driven ratchet motion of a skyrmion microcrystal and topological magnon Hall effect. , 2014, Nature materials.

[14]  A. N’Diaye,et al.  Room temperature skyrmion ground state stabilized through interlayer exchange coupling , 2015 .

[15]  S. Parkin,et al.  Magnetic Domain-Wall Racetrack Memory , 2008, Science.

[16]  A. Fert,et al.  Skyrmions at room temperature : From magnetic thin films to magnetic multilayers , 2015, 1502.07853.

[17]  You-Quan Li,et al.  A mechanism to pin skyrmions in chiral magnets , 2012, Journal of physics. Condensed matter : an Institute of Physics journal.

[18]  A. Fert,et al.  Nucleation, stability and current-induced motion of isolated magnetic skyrmions in nanostructures. , 2013, Nature nanotechnology.

[19]  Highly improved staggered quarks on the lattice with applications to charm physics , 2006, hep-lat/0610092.

[20]  F. Nori,et al.  Collective interaction-driven ratchet for transporting flux quanta. , 2001, Physical review letters.

[21]  Bartosz A. Grzybowski,et al.  Directing cell motions on micropatterned ratchets , 2009 .

[22]  M. Mochizuki,et al.  Universal current-velocity relation of skyrmion motion in chiral magnets , 2013, Nature Communications.

[23]  Victor V. Moshchalkov,et al.  Controlled multiple reversals of a ratchet effect , 2006, Nature.

[24]  Y. Tokura,et al.  Skyrmion flow near room temperature in an ultralow current density , 2012, Nature Communications.

[25]  J. White,et al.  A new class of chiral materials hosting magnetic skyrmions beyond room temperature , 2015, Nature communications.

[26]  Franco Nori,et al.  A Superconducting Reversible Rectifier That Controls the Motion of Magnetic Flux Quanta , 2003, Science.

[27]  Michael D. Schneider,et al.  Dynamics and inertia of skyrmionic spin structures , 2015, Nature Physics.

[28]  M. Weitz,et al.  Directed Transport of Atoms in a Hamiltonian Quantum Ratchet , 2009, Science.

[29]  P. Reimann Brownian motors: noisy transport far from equilibrium , 2000, cond-mat/0010237.

[30]  Current-driven dynamics of skyrmions stabilized in MnSi nanowires revealed by topological Hall effect , 2015, Nature communications.

[31]  A. Saxena,et al.  Driven Skyrmions and dynamical transitions in chiral magnets. , 2013, Physical review letters.

[32]  C. Reichhardt,et al.  Collective transport properties of driven Skyrmions with random disorder. , 2014, Physical review letters.

[33]  P. Böni,et al.  Skyrmion Lattice in a Chiral Magnet , 2009, Science.

[34]  A. Rosch,et al.  Capturing of a magnetic skyrmion with a hole , 2014, 1411.2857.

[35]  Ernst Helmut Brandt,et al.  The flux-line lattice in superconductors , 1995, supr-con/9506003.

[36]  C. Reichhardt,et al.  Quantized transport for a skyrmion moving on a two-dimensional periodic substrate , 2015, 1501.04126.

[37]  P. Böni,et al.  Spin Transfer Torques in MnSi at Ultralow Current Densities , 2010, Science.

[38]  S. Heinze,et al.  Spontaneous atomic-scale magnetic skyrmion lattice in two dimensions , 2011 .

[39]  A. Ajdari,et al.  Directional motion of brownian particles induced by a periodic asymmetric potential , 1994, Nature.