Modified dispersion law for spin waves coupled to a superconductor

Abstract: In this work, we consider dispersion laws of spin waves that propagate in a ferromagnet/superconductor bilayer, specifically in a ferromagnetic film coupled inductively to a superconductor. The coupling is viewed as an interaction of a spin wave in a ferromagnetic film with its mirrored image generated by the superconductor. We show that, in general, the coupling enhances substantially the phase velocity of magnons in in-plane spin wave geometries. In addition, a heavy nonreciprocity of the dispersion law is o… Show more

“…Blue solid curves show a typical dispersion curve for MSSW in the plain F film that is obtained with simulations in the absence of any contribution from S subsystem. Simulation results are well confirmed by the analytical dispersion relation [53], shown with blue dashed curves. Red solid and dashed lines show the dispersion curve of MSSW in the S-F bilayer in the presence of magnetostatic interaction between the S and F subsystems.…”

“…The excitation field pulse has the maximum frequency f max = 30 GHz, the Gaussian spatial profile with the width at half-maximum of 200 nm, and the amplitude of 0.001 Ms. In simulations, the diamagnetic (Meissner) contribution of S subsystem on magnetization dynamics is accounted via the method of images [17,53] in the case of continuous S layers and via the diamagnetic representation of superconductors [18,19] in the case of finite-size S elements. The effect of the superconducting proximity in S-F-S is represented by a local uniaxial anisotropy field μ 0 H s = 0.07 T that corresponds to the S1 sample [see Fig.…”

“…Red solid and dashed lines show the dispersion curve of MSSW in the S-F bilayer in the presence of magnetostatic interaction between the S and F subsystems. The magnetostatic interaction is accounted for using the method of images [17,53]. It shows that in the presence of magnetostatic interaction the dispersion is nonreciprocal: the frequency pass band for positive wave numbers is approximately doubled as compared to the pass band for negative wave numbers.…”

“…The nonreciprocity is a known property of MSSWs, which emerges due to asymmetry of the ferromagnetic film across its thickness or due to asymmetry of its surrounding (see Ref. [53] for details). Purple solid and dashed lines show the dispersion curve of MSSW in the S-F-S three layer in the presence of the proximity-induced uniaxial anisotropy H s but the absence of magnetostatic interaction between the S and F subsystems.…”

“…For this structure similar geometrical parameters are considered: the lattice period a = 1 μm, the width of F-S section 0.5 μm, and the thickness of the upper S layers 120 nm. Calculating this spectrum the diamagnetic representation of S stripes [18,19], the image method [17,53] is used for finite-size and continuous superconducting elements, respectively. The effect of the proximity in S-F-S sections is represented by the same local anisotropy H s .…”

Magnetization Dynamics in Proximity-Coupled Superconductor-Ferromagnet-Superconductor Multilayers

“…Blue solid curves show a typical dispersion curve for MSSW in the plain F film that is obtained with simulations in the absence of any contribution from S subsystem. Simulation results are well confirmed by the analytical dispersion relation [53], shown with blue dashed curves. Red solid and dashed lines show the dispersion curve of MSSW in the S-F bilayer in the presence of magnetostatic interaction between the S and F subsystems.…”

“…The excitation field pulse has the maximum frequency f max = 30 GHz, the Gaussian spatial profile with the width at half-maximum of 200 nm, and the amplitude of 0.001 Ms. In simulations, the diamagnetic (Meissner) contribution of S subsystem on magnetization dynamics is accounted via the method of images [17,53] in the case of continuous S layers and via the diamagnetic representation of superconductors [18,19] in the case of finite-size S elements. The effect of the superconducting proximity in S-F-S is represented by a local uniaxial anisotropy field μ 0 H s = 0.07 T that corresponds to the S1 sample [see Fig.…”

“…Red solid and dashed lines show the dispersion curve of MSSW in the S-F bilayer in the presence of magnetostatic interaction between the S and F subsystems. The magnetostatic interaction is accounted for using the method of images [17,53]. It shows that in the presence of magnetostatic interaction the dispersion is nonreciprocal: the frequency pass band for positive wave numbers is approximately doubled as compared to the pass band for negative wave numbers.…”

“…The nonreciprocity is a known property of MSSWs, which emerges due to asymmetry of the ferromagnetic film across its thickness or due to asymmetry of its surrounding (see Ref. [53] for details). Purple solid and dashed lines show the dispersion curve of MSSW in the S-F-S three layer in the presence of the proximity-induced uniaxial anisotropy H s but the absence of magnetostatic interaction between the S and F subsystems.…”

“…For this structure similar geometrical parameters are considered: the lattice period a = 1 μm, the width of F-S section 0.5 μm, and the thickness of the upper S layers 120 nm. Calculating this spectrum the diamagnetic representation of S stripes [18,19], the image method [17,53] is used for finite-size and continuous superconducting elements, respectively. The effect of the proximity in S-F-S sections is represented by the same local anisotropy H s .…”

Magnetization Dynamics in Proximity-Coupled Superconductor-Ferromagnet-Superconductor Multilayers

Ferromagnet/Superconductor Hybrid Magnonic Metamaterials

Controlled Vortex Formation at Nanostructured Superconductor/Ferromagnetic Junctions