All-magnonic Repeater Based on Bistability

Overview

Journal Nat Commun

Specialty Biology

Date 2024 Aug 31

PMID 39217155

Authors

Qi Wang

Roman Verba

Kristyna Davidkova

Bjorn Heinz

Shixian Tian

Yiheng Rao

Mengying Guo

Xueyu Guo

Carsten Dubs

Philipp Pirro

Andrii V Chumak

Affiliations

Soon will be listed here.

Abstract

Bistability, a universal phenomenon found in diverse fields such as biology, chemistry, and physics, describes a scenario in which a system has two stable equilibrium states and resets to one of the two states. The ability to switch between these two states is the basis for a wide range of applications, particularly in memory and logic operations. Here, we present a universal approach to achieve bistable switching in magnonics, the field processing data using spin waves. A pronounced bistable window is observed in a 1 μm wide magnonic conduit under an external rf drive. The system is characterized by two magnonic stable states defined as low and high spin-wave amplitude states. The switching between these two states is realized by another propagating spin wave sent into the rf driven region. This magnonic bistable switching is used to design a magnonic repeater, which receives the original decayed and distorted spin wave and regenerates a new spin wave with amplified amplitude and normalized phase. Our magnonic repeater can be installed at the inputs of each magnonic logic gate to overcome the spin-wave amplitude degradation and phase distortion during previous propagation and achieve integrated magnonic circuits or magnonic neuromorphic networks.

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