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

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 K), where the phase shift is expected to show a plateau at π/2 for an ideal Kondo singlet ground state. Our device is tuned such that the ratio /U of level width to charging energy U is quite large ( 0.5 rather than 1). This situation is commonly used in GaAs quantum dots to ensure Kondo temperatures large enough ( 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 /U 1 needed to ensure a well-defined local moment. Our measured phase evolves monotonically by π across the two Coulomb peaks, but without being locked at π/2 in the Kondo valley for T T K, due to a significant influence of large /U. Only when /U is reduced sufficiently does the phase start to be locked around π/2 and develops into a plateau at π/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.