Magnetic field dependence of the thermopower of Kondo-correlated quantum dots

TL;DR

This study uses numerical renormalization group methods to analyze how magnetic fields influence the thermopower in Kondo-correlated quantum dots, revealing additional sign changes and providing insights into recent experimental observations.

Contribution

It introduces a detailed NRG analysis of magnetic field effects on thermopower in Kondo quantum dots, extending understanding beyond zero-field behavior.

Findings

Magnetic field induces an additional sign change in thermopower at a specific temperature.

The field $B_0$ causing this sign change exceeds the Kondo field $B_c$ and is comparable to it.

Results are validated against higher-order Fermi-liquid calculations.

Abstract

Recent experiments have measured the signatures of the Kondo effect in the zero-field thermopower of strongly correlated quantum dots [Svilans {\em et al.,} Phys. Rev. Lett. {\bf 121}, 206801 (2018); Dutta {\em et al.,} Nano Lett. {\bf 19}, 506 (2019)]. They confirm the predicted Kondo-induced sign change in the thermopower, upon increasing the temperature through a gate-voltage dependent value $T_{1}\gtrsim T_{\rm K}$, where $T_{\rm K}$ is the Kondo temperature. Here, we use the numerical renormalization group (NRG) method to investigate the effect of a finite magnetic field $B$ on the thermopower of such quantum dots. We show that, for fields $B$ exceeding a gate-voltage dependent value $B_{0}$, an additional sign change takes place in the Kondo regime at a temperature $T_{0}(B\geq B_{0})>0$ with $T_0<T_1$. The field $B_{0}$ is comparable to, but larger than, the field $B_{c}$ at which the zero-temperature spectral function splits in a magnetic field. The validity of the NRG results for $B_{0}$ are checked by comparison with asymptotically exact higher-order Fermi-liquid calculations [Oguri {\em et al.,} Phys. Rev. B {\bf 97}, 035435 (2018)]. Our calculations clarify the field-dependent signatures of the Kondo effect in the thermopower of Kondo-correlated quantum dots and explain the recently measured trends in the $B$-field dependence of the thermoelectric response of such systems [Svilans {\em et al.,} Phys. Rev. Lett. {\bf 121}, 206801 (2018)].