Off-resonant detection of domain wall oscillations using deterministically placed nanodiamonds

npj Spintronics Pub Date : 2023-12-13 DOI:10.1038/s44306-023-00002-3

Jeffrey Rable, Jyotirmay Dwivedi, Nitin Samarth

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Abstract

Nitrogen-vacancy (NV) centers in diamond offer a sensitive method of measuring the spatially localized dynamics of magnetization and associated spin textures in ferromagnetic materials. We use NV centers in a deterministically positioned nanodiamond to demonstrate off-resonant detection of microwave field-driven GHz-scale oscillations of a single domain wall (DW). The technique exploits the enhanced relaxation of NV center spins due to the broadband stray field noise generated by an oscillating DW pinned at an engineered defect in a lithographically patterned ferromagnetic nanowire. Discrepancies between the observed DW oscillation frequency and predictions from micromagnetic simulations suggest extreme sensitivity of DW dynamics to patterning imperfections such as edge roughness. These experiments and simulations identify potential pathways toward quantum spintronic devices that exploit current-driven DWs as nanoscale microwave generators for qubit control, greatly increasing the driving field at an NV center and thus drastically reducing the π pulse time.

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利用确定性放置的纳米金刚石对域壁振荡进行非共振探测

金刚石中的氮空位（NV）中心为测量铁磁材料中磁化和相关自旋纹理的空间局部动态提供了一种灵敏的方法。我们利用确定性定位的纳米金刚石中的 NV 中心，展示了对单个畴壁（DW）的微波场驱动 GHz 级振荡的非共振探测。该技术利用了 NV 中心自旋的增强弛豫，这种弛豫是由于振荡的 DW 定位于光刻图案化铁磁纳米线的工程缺陷处而产生的宽带杂散场噪声造成的。观察到的 DW 振荡频率与微磁模拟预测之间的差异表明，DW 动态对图案缺陷（如边缘粗糙度）极为敏感。这些实验和模拟确定了通向量子自旋电子器件的潜在途径，即利用电流驱动的 DW 作为纳米级微波发生器进行量子比特控制，大大增加 NV 中心的驱动场，从而大幅缩短 π 脉冲时间。

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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npj Spintronics

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