利用手性纳米结构构建一维涡旋链

Construction of 1D Vortex Chain Using a Chiral Nanostructure.

作者信息

Li Zhenghua, Dong Bin, He Yangyang, Li Xiang, Chen Aiying

机构信息

Key Laboratory of New Energy and Rare Earth Resource Utilization of State Ethnic Affairs Commission School of Physics and Materials Engineering Dalian Minzu University Dalian 116600 China.

School of Materials Science and Engineering University of Shanghai for Science and Technology Shanghai 200093 China.

出版信息

Adv Sci (Weinh). 2020 Jul 1;7(16):2001040. doi: 10.1002/advs.202001040. eCollection 2020 Aug.

DOI:10.1002/advs.202001040

PMID:32832359

原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC7435250/

Abstract

The construction and control of high-order coupled vortices are a significant challenge for promoting the application of magnetic vortices. Thus far, only double-coupled vortices have been produced and modulated in some ferromagnetic nanostructures. Here, an effective approach is provided to obtain a high-order coupled vortex structure by using a chiral nanostructure. Double-vortex, triple-vortex, and -vortex chains can be successfully constructed using structured FeN nanostrips and bias nanomagnets. The designed chiral nanostructure cannot only control the transport and hybridization of vortices but also modulate the domain walls of the vortex chain for spin wave (SW) propagation. At the exciting frequency of 1.2 GHz, the SW propagates along the domain walls formed in the vortex chain. Upon increasing the frequency to 5.0 GHz, the SW gradually spreads from the domain walls into domains. This technique will present a new perspective for the design and application of magnetic vortex-based devices.

摘要

高阶耦合涡旋的构建与控制是推动磁涡旋应用的一项重大挑战。到目前为止，仅在一些铁磁纳米结构中产生并调制了双耦合涡旋。在此，提供了一种通过使用手性纳米结构来获得高阶耦合涡旋结构的有效方法。利用结构化的FeN纳米带和偏置纳米磁体可以成功构建双涡旋、三涡旋和涡旋链。所设计的手性纳米结构不仅可以控制涡旋的传输和杂化，还能调制涡旋链的畴壁以实现自旋波（SW）传播。在1.2 GHz的激发频率下，自旋波沿着在涡旋链中形成的畴壁传播。当频率增加到5.0 GHz时，自旋波逐渐从畴壁扩散到畴内。该技术将为基于磁涡旋的器件的设计和应用提供一个新的视角。

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利用手性纳米结构构建一维涡旋链

Construction of 1D Vortex Chain Using a Chiral Nanostructure.

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