Electrically controlled nonvolatile switching of single-atom magnetism in a Dy@C84 single-molecule transistor

arXiv - PHYS - Atomic and Molecular Clusters Pub Date : 2024-03-17 DOI:arxiv-2403.11137

Feng Wang, Wangqiang Shen, Yuan Shui, Jun Chen, Huaiqiang Wang, Rui Wang, Yuyuan Qin, Xuefeng Wang, Jianguo Wan, Minhao Zhang, Xing Lu, Tao Yang, Fengqi Song

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Abstract

Single-atom magnetism switching is a key technique towards the ultimate data storage density of computer hard disks and has been conceptually realized by leveraging the spin bistability of a magnetic atom under a scanning tunnelling microscope. However, it has rarely been applied to solid-state transistors, an advancement that would be highly desirable for enabling various applications. Here, we demonstrate realization of the electrically controlled Zeeman effect in Dy@C84 single-molecule transistors, thus revealing a transition in the magnetic moment from 3.8 {\mu}B to 5.1 {\mu}B for the ground-state GN at an electric field strength of 3-10 MV/cm. The consequent magnetoresistance significantly increases from 600% to 1100% at the resonant tunneling point. Density functional theory calculations further corroborate our realization of nonvolatile switching of single-atom magnetism, and the switching stability emanates from an energy barrier of 92 meV for atomic relaxation. These results highlight the potential of using endohedral metallofullerenes for high-temperature, high-stability, high-speed, and compact single-atom magnetic data storage.

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Dy@C84 单分子晶体管中的单原子磁性电控非易失性开关

单原子磁性切换是实现计算机硬盘终极数据存储密度的一项关键技术，在扫描隧道显微镜下利用磁性原子的自旋双稳态性在概念上已经实现。在这里，我们展示了在 Dy@C84 单分子晶体管中实现的电控泽曼效应，从而揭示了在 3-10 MV/cm 的电场强度下，基态 GN 的磁矩从 3.8 {\mu}B 转变为 5.1 {\mu}B 。密度泛函理论计算进一步证实了我们实现了单原子磁性的非易失性切换，而切换的稳定性源于原子弛豫的 92 meV 能量势垒。这些结果凸显了利用内切金属富勒烯进行高温、高稳定性、高速和紧凑型单原子磁性数据存储的潜力。

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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arXiv - PHYS - Atomic and Molecular Clusters

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