Reprogrammability of magnonic band structure in layered permalloy/Cu/permalloy nanowires is demonstrated to depend on the relative orientation of the two layers magnetization. By using Brillouin light spectroscopy, we show that when the layers are aligned parallel two dispersive modes, with positive and negative group velocity, are observed while when the magnetic layers are aligned antiparallel, only one dispersive mode, with positive group velocity, is detected. Our findings are successfully compared and interpreted in terms of a microscopic (Hamiltonian-based) method. An explanation for the observed behavior can be attributed to mode-mixing (or hybridization) effect when the two magnetic layers are aligned antiparallel. This work opens the path to magnetic field-controlled reconfigurable magnonic crystals with multimodal frequency transmission characteristics.
Reprogrammable magnonic band structure of layered permalloy/Cu/permalloy nanowires
Gubbiotti G;
2018
Abstract
Reprogrammability of magnonic band structure in layered permalloy/Cu/permalloy nanowires is demonstrated to depend on the relative orientation of the two layers magnetization. By using Brillouin light spectroscopy, we show that when the layers are aligned parallel two dispersive modes, with positive and negative group velocity, are observed while when the magnetic layers are aligned antiparallel, only one dispersive mode, with positive group velocity, is detected. Our findings are successfully compared and interpreted in terms of a microscopic (Hamiltonian-based) method. An explanation for the observed behavior can be attributed to mode-mixing (or hybridization) effect when the two magnetic layers are aligned antiparallel. This work opens the path to magnetic field-controlled reconfigurable magnonic crystals with multimodal frequency transmission characteristics.I documenti in IRIS sono protetti da copyright e tutti i diritti sono riservati, salvo diversa indicazione.
