Transition between SU(4) and SU(2) Kondo effect

TL;DR

This paper investigates how the Kondo effect transitions between SU(4) and SU(2) symmetries in a generalized Anderson model, analyzing spectral density evolution and Kondo temperature changes as the energy separation varies.

Contribution

It provides a detailed analysis of the spectral density evolution and Kondo temperature variation during the transition between SU(4) and SU(2) Kondo regimes using the non-crossing approximation.

Findings

Kondo peak splits as energy separation increases.

Kondo temperature decreases significantly with increasing energy separation.

Spectral density shifts above the Fermi energy for higher-energy doublet.

Abstract

Motivated by experiments in nanoscopic systems, we study a generalized Anderson, which consists of two spin degenerate doublets hybridized to a singlet by promotion of an electron to two conduction bands, as a function of the energy separation $\delta$ between both doublets. For $\delta$=0 or very large, the model is equivalent to a one-level SU(N) Anderson model, with N=4 and 2 respectively. We study the evolution of the spectral density for both doublets ($\rho_{1 \sigma}(\omega)$ and $\rho_{2 \sigma}(\omega)$) and their width in the Kondo limit as $\delta$ is varied, using the non-crossing approximation (NCA). As $\delta$ increases, the peak at the Fermi energy in the spectral density (Kondo peak) splits and the density of the doublet of higher energy $\rho_{2 \sigma}(\omega)$ shifts above the Ferrmi energy. The Kondo temperature $T_K$ (determined by the half width at half maximum of the Kondo peak in density of the doublet of lower energy $\rho_{1 \sigma}(\omega)$) decreases dramatically. The variation of $T_K$ with $\delta$ is reproduced by a simple variational calculation.