Low-temperature behavior of transmission phase shift across a Kondo correlated quantum dot

TL;DR

This study investigates the transmission phase shift in a Kondo quantum dot at low temperatures, revealing how increased charge fluctuations due to larger level width to charging energy ratio affect the expected phase plateau.

Contribution

It provides experimental evidence showing the impact of large /U ratios on the transmission phase behavior in Kondo quantum dots, extending understanding beyond the ideal /U 1 regime.

Findings

Phase evolves monotonically by a across Coulomb peaks.

No a/2 plateau observed at large /U.

Reducing /U leads to phase locking at a/2.

Abstract

We study the transmission phase shift across a Kondo correlated quantum dot in a GaAs heterostructure at temperatures below the Kondo temperature ($T < T_{\rm K}$), where the phase shift is expected to show a plateau at $\pi/2$ for an ideal Kondo singlet ground state. Our device is tuned such that the ratio $\Gamma/U$ of level width $\Gamma$ to charging energy $U$ is quite large ($\lesssim 0.5$ rather than $\ll 1$). This situation is commonly used in GaAs quantum dots to ensure Kondo temperatures large enough ($\simeq 100$ mK here) to be experimentally accessible; however it also implies that charge fluctuations are more pronounced than typically assumed in theoretical studies focusing on the regime $\Gamma/U \ll 1$ needed to ensure a well-defined local moment. Our measured phase evolves monotonically by $\pi$ across the two Coulomb peaks, but without being locked at $\pi/2$ in the Kondo valley for $T \ll T_{\rm K}$, due to a significant influence of large $\Gamma/U$. Only when $\Gamma/U$ is reduced sufficiently does the phase start to be locked around $\pi/2$ and develops into a plateau at $\pi/2$. Our observations are consistent with numerical renormalization group calculations, and can be understood as a direct consequence of the Friedel sum rule that relates the transmission phase shift to the local occupancy of the dot, and thermal average of a transmission coefficient through a resonance level near the Fermi energy.