What question did this study set out to answer?

The research aims to analyze noise characteristics and conductance in an N-level Kondo system using a theoretical framework.

April 16, 2026Open Access

Fractional shot noise of an SU( N ) Kondo system

Key Points

The research aims to analyze noise characteristics and conductance in an N-level Kondo system using a theoretical framework.
Applied the Kotliar–Ruckentein slave boson approach for N-level Anderson model.
Defined noninteracting quasiparticles in a multilevel quantum dot.
Analyzed nonlinear conductance and shot noise using Fermi liquid theory.
Considered contributions from two-quasiparticle and three-body correlations.
Identified Kondo resonance transmission coefficients impacting linear noise.
Nonlinear shot noise primarily driven by two-quasiparticle scattering.
Showed the necessity of accounting for three-body correlations far from electron–hole symmetry.

Abstract

We consider transport through a multilevel interacting quantum dot (N-QD) in the Kondo regime. Using the Kotliar–Ruckentein slave boson approach (SBMFA) for an N -level Anderson model, we define effectively noninteracting quasiparticles of the SU( N ) Kondo system ( N = 2, 3, 4, 5, 6). Kondo resonance transmission coefficients determine linear noise describing quasiparticle partitioning. To discuss nonlinear conductance, susceptibilities, and shot noise in the strong coupling regime, we apply Fermi liquid theory with parameters expressed by susceptibilities of pseudofermions determined within SBMFA. Nonlinear shot noise is dominated by two-quasiparticle scattering. However, we demonstrate that for occupation regions distant from the electron–hole symmetry point, the role of three-body correlations must be considered.

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Fractional shot noise of an SU( N ) Kondo system

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Abstract

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