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Paper detail

Spin-wave phase inverter upon a single nanodefect

Local modification of magnetic properties of nanoelements is a key to design future-generation magnonic devices, in which information is carried and processed via spin waves. One of the biggest challenges here is to fabricate simple and miniature phase-controlling elements with broad tunability. Here, we successfully realize such spin-wave phase shifter upon a single nanogroove milled by focused ion beam in a Co-Fe microsized magnonic waveguide. By varying the groove depth and the in-plane bias magnetic field we continuously tune the spin-wave phase and experimentally evidence a complete phase inversion. The microscopic mechanism of the phase shift is based on the combined action of the nanogroove as a geometrical defect and the lower spin-wave group velocity in the waveguide under the groove where the magnetization is reduced due to the incorporation of Ga ions during the ion-beam milling. The proposed phase shifter can easily be on-chip integrated with spin-wave logic gates and other magnonic devices. Our findings are crucial for designing nano-magnonic circuits and for the development of spin-wave nano-optics.

preprint2019arXivOpen access
O. V. DobrovolskiyR. SachserS. A. BunyaevD. NavasV. M. BevzM. ZelentW. SmigajJ. RychlyM. KrawczykR. V. VovkM. HuthG. N. Kakazei
cond-mat.mes-hall
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O. V. DobrovolskiyR. SachserS. A. BunyaevD. NavasV. M. BevzM. ZelentW. SmigajJ. RychlyM. KrawczykR. V. VovkM. HuthG. N. Kakazei

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