Exploring the Kondo Effect in Strained Kagome Nanoribbons

TL;DR

This study investigates how uniaxial strain affects the Kondo effect in kagome nanoribbons, revealing that strain can precisely tune magnetic impurity screening and Kondo temperature, with implications for understanding correlated-electron phenomena.

Contribution

It demonstrates the use of the single-impurity Anderson model and numerical renormalization group to analyze strain-controlled Kondo effects in kagome nanoribbons, highlighting the role of impurity location and local environment.

Findings

Strain enables precise control over Kondo effect strength.

Symmetric local environments can suppress hybridization.

Impurity position near edge states significantly affects Kondo temperature.

Abstract

Metallic kagome systems have attracted considerable interest in recent years, as they provide a rich platform for studying phenomena associated with their distinctive band structure. The coexistence of bands with Dirac points similar to those in graphene, along with a completely flat band, makes this an ideal structure for investigating how lattice symmetries may protect topological and many-body correlation effects. Since applied strain can break lattice symmetries and modify the electronic structure, understanding how strain influences phenomena such as the Kondo effect in kagome materials may provide essential insights into correlated-electron behavior. We employ the single-impurity Anderson model and the numerical renormalization group to analyze the Kondo effect in kagome zigzag nanoribbons under uniaxial strain. We find that strain manipulation enables precise control over the strength of the Kondo effect on an impurity hybridized on the ribbon with different coordination environments, and that symmetric local environments may result in strong suppression of the effective hybridization due to orbital interference. We find that the specific location of the impurity on the ribbon, especially when the Fermi energy lies close to weakly dispersive edge states, can lead to significant changes in the characteristic Kondo temperature. Such sensitivity may be used to provide unique information on the local density of states of a system. These results demonstrate that strain is a powerful tuning parameter in kagome nanoribbons, strongly modifying the screening of magnetic impurities.