Exchange-based noise spectroscopy of a single precessing spin with scanning tunnelling microscopy

Philosophical Magazine Part B Pub Date : 2002-06-17 DOI:10.1080/13642810208223166

A. Balatsky, Y. Manassen, R. Salem

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引用次数: 17

Abstract

Abstract Electron spin resonance-scanning tunnelling microscopy is an emerging technique which is capable of detecting the precession of a single spin. We discuss a mechanism based on direct exchange coupling between the tunnelling electrons and the local precessing spin S. We claim that, since the number of tunnelling electrons in a single precessing period is small (about 20), one may expect a net temporary polarization within this period which will couple via exchange interaction to the localized spin. This coupling will modulate the tunnelling barrier with the Larmor frequency of the precessing spin ωL. This modulation, although randomly changing from cycle to cycle, will produce an elevated noise in the current at ωL. We find that for relevant values of parameters the signal-to-noise ratio in the spectral characteristic is 2–4 and is comparable with the values of the signal-to-noise ratio reported by Manassen and co-workers and by Durkan and Welland. The magnitude of the current fluctuation is a relatively weak increasing function of the dc and the magnetic field. The linewidth produced by the back action effect of tunnelling electrons on the precessing spin is also discussed.

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用扫描隧道显微镜研究单进动自旋的交换噪声光谱

电子自旋共振扫描隧道显微镜是一种能够检测单个自旋进动的新兴技术。我们讨论了一种基于隧道电子和局部自旋s之间直接交换耦合的机制。我们声称，由于在单个处理周期内隧道电子的数量很少(约20)，因此可以预期在此周期内存在净暂时极化，该极化将通过交换相互作用与局域自旋耦合。这种耦合将以进动自旋的拉莫尔频率ωL调制隧穿势垒。这种调制虽然随周期随机变化，但会在ωL的电流中产生升高的噪声。我们发现，对于参数的相关值，频谱特征中的信噪比为2-4，与Manassen及其同事以及Durkan和Welland报告的信噪比值相当。电流波动的幅度是直流电和磁场相对较弱的递增函数。讨论了隧穿电子对进动自旋的反作用所产生的线宽。

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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Philosophical Magazine Part B

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