Experimental Demonstration of a Spin-Wave Lens Designed With Machine Learning

IF 1.1 4区物理与天体物理 Q4 ENGINEERING, ELECTRICAL & ELECTRONIC

IEEE Magnetics Letters Pub Date : 2022-09-26 DOI:10.1109/LMAG.2022.3209647

Martina Kiechle;Levente Maucha;Valentin Ahrens;Carsten Dubs;Wolfgang Porod;Gyorgy Csaba;Markus Becherer;Adam Papp

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引用次数: 6

Abstract

In this letter, we present the design and experimental realization of a device that acts like a spin-wave lens i.e., it focuses spin waves to a specified location. The structure of the lens does not resemble any conventional lens design. It is a nonintuitive pattern produced by a machine-learning algorithm. As a spin-wave design tool, we used our custom micromagnetic solver SpinTorch, which has built-in automatic gradient calculation and can perform backpropagation through time for spin-wave propagation. The training itself is performed with the saturation magnetization of a yttrium-iron-garnet (YIG) film as a variable parameter, with the goal to guide spin waves to a predefined location. We verified the operation of the device in the widely used mumax

$^{3}$

micromagnetic solver, and by experimental realization. For the experimental implementation, we developed a technique to create effective saturation-magnetization landscapes in YIG by direct focused-ion-beam (FIB) irradiation. This allows us to rapidly transfer the nanoscale design patterns to the YIG medium, without patterning the material by etching. We measured the effective saturation magnetization corresponding to the FIB dose levels in advance and used this mapping to translate the designed scatterer to the required dose levels. Our demonstration serves as a proof of concept for a workflow that can be used to realize more sophisticated spin-wave devices with complex functionality, e.g., spin-wave signal processors, or neuromorphic devices.

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利用机器学习设计的自旋波透镜的实验演示

在这封信中，我们介绍了一种类似于自旋波透镜的装置的设计和实验实现，即它将自旋波聚焦到指定的位置。透镜的结构与任何传统的透镜设计都不相似。这是一种由机器学习算法产生的非直觉模式。作为一种自旋波设计工具，我们使用了我们定制的微磁解算器SpinTorch，该解算器具有内置的自动梯度计算功能，可以通过时间执行自旋波传播的反向传播。训练本身是以钇铁石榴石（YIG）膜的饱和磁化强度作为可变参数进行的，目的是将自旋波引导到预定位置。我们在广泛使用的mumax$^{3}$微磁求解器中验证了该器件的操作，并通过实验实现。为了实现实验，我们开发了一种通过直接聚焦离子束（FIB）照射在YIG中创建有效饱和磁化景观的技术。这使我们能够快速将纳米级设计图案转移到YIG介质上，而无需通过蚀刻对材料进行图案化。我们提前测量了与FIB剂量水平相对应的有效饱和磁化强度，并使用该映射将设计的散射体转换为所需的剂量水平。我们的演示证明了工作流的概念，该工作流可用于实现具有复杂功能的更复杂的自旋波设备，例如，自旋波信号处理器或神经形态设备。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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来源期刊

IEEE Magnetics Letters PHYSICS, APPLIED-

CiteScore

2.40

自引率

0.00%

发文量

期刊介绍： IEEE Magnetics Letters is a peer-reviewed, archival journal covering the physics and engineering of magnetism, magnetic materials, applied magnetics, design and application of magnetic devices, bio-magnetics, magneto-electronics, and spin electronics. IEEE Magnetics Letters publishes short, scholarly articles of substantial current interest. IEEE Magnetics Letters is a hybrid Open Access (OA) journal. For a fee, authors have the option making their articles freely available to all, including non-subscribers. OA articles are identified as Open Access.