# Inducing Kondo Screening of Vacancy Magnetic Moments in Graphene with   Gating and Local Curvature

**Authors:** Yuhang Jiang, Jinhai Mao, Po-Wei Lo, Daniel May, Guohong Li, Guang-Yu, Guo, Frithjof B. Anders, Takashi Taniguchi, Kenji Watanabeand, Eva Y. Andrei

arXiv: 1907.10090 · 2019-07-25

## TL;DR

This study demonstrates the induction of Kondo screening of vacancy magnetic moments in graphene, revealing a quantum phase transition controllable via gating and local curvature, with implications for magnetic state manipulation.

## Contribution

It provides experimental evidence of Kondo screening and a quantum phase transition in graphene, tunable by local curvature and gate voltage, advancing understanding of magnetic moments in pseudogap systems.

## Key findings

- Kondo screening observed in graphene vacancy moments.
- Quantum phase transition between screened and unscreened states mapped.
- Magnetic moments can be turned on/off with gating and curvature adjustments.

## Abstract

In normal metals, the magnetic-moment of impurity-spins disappears below a characteristic Kondo temperature, TK. This marks the formation of a polarized cloud of conduction band electrons that screen the magnetic moment . In contrast, moments embedded in insulators remain unscreened at all temperatures. This raises the question about the fate of magnetic-moments in intermediate, pseudogap systems, such as graphene. In these systems coupling between the local moment and the conduction band electrons is predicted to drive a quantum phase-transition between a local-moment phase and a Kondo-screened singlet phase as illustrated in Fig. 1A. However, attempts to experimentally confirm these predictions and their intriguing consequences such as the ability to electrostatically tune magnetic-moments, have been elusive. Here we report the observation of Kondo screening and the quantum phase-transition between screened and unscreened phases of vacancy magnetic-moments in graphene. Using scanning-tunneling-microscopy (STM), spectroscopy (STS) and numerical-renormalization-group (NRG) calculations, we identified Kondo-screening by its spectroscopic signature and mapped the quantum phase-transition as a function of coupling strength and chemical potential. We show that the coupling strength can be tuned across this transition by variations in the local curvature and furthermore that the transition makes it possible to turn the magnetic-moment on and off with a gate voltage.

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Source: https://tomesphere.com/paper/1907.10090