Kondo induced {\pi}-phase shift of microwave photons in a circuit quantum electrodynamics architecture

TL;DR

This paper reports the first observation of a a-phase shift in microwave photons caused by the Kondo effect in a graphene double quantum dot within a circuit QED setup, revealing many-body physics in light-matter interactions.

Contribution

It demonstrates the experimental detection of a a-phase shift due to Kondo resonance in a circuit QED architecture, linking many-body physics with microwave photon behavior.

Findings

Observed a-phase shift in microwave photons linked to Kondo resonance

Kondo temperature measured at approximately 550 mK, consistent with conductance data

Identified an SU(4) Fermi-liquid ground state in the system

Abstract

Mesoscopic systems constitute appealing platforms to study many-body physics with light and matter degrees of freedom. The Kondo effect refers to the screening of a spin-1/2 impurity by a cloud of conduction electrons, then forming a many-body Fermi liquid ground state. The Kondo resonance produces a phase shift in the transmitted electronic wave packet which depends on the symmetry and nature of the many-body ground state. Theoretical calculations suggest that the Kondo resonance can interact with the irradiation photon field and should give rise to a {\pi}-phase shift of the photon signal in the case where the ground state is a Fermi liquid. This {\pi}-phase shift of microwave photon is driven from the Korringa-Shiba relation of quantum impurity Fermi-liquid ground states. We report the first observation of such a {\pi}-phase shift in a graphene double quantum dot within a circuit quantum electrodynamics architecture where the microwave photons couple to the pseudo-spin or charge degrees of freedom. The observed Kondo temperature TK ~ 550 mK is in agreement with DC conductance measurements. All our results support the formation of a Kondo resonance located above the Fermi level of the electronic reservoirs and the occurrence of an SU(4) Fermi-liquid ground state. We finally study how the Kondo-photon interactions can be tuned by inter-dot electron tunnel coupling strengths. Our experimental achievements may contribute to a better understanding of many-body physics in hybrid circuit systems, and open up new applications in atomic thin materials from the light-matter interaction.