Thermoelectric effect in the Kondo dot side-coupled to a Majorana fermion

Abstract

We investigate the linear thermoelectric response of an interacting quantum dot side-coupled by one of two Majorana fermions (MFs) formed at the ends of a topological superconducting wire. We employ the numerical renormalization group technique to obtain the thermoelectrical conductance L as well as the electrical conductance G when the background temperature T and the dot gate are tuned. We distinguish two transport regimes in which L displays different features: the weak- (m < TK) and strong-coupling (m > TK) regimes, where m and TK are the Majorana-dot coupling and the Kondo temperature, respectively. For an ideal (infinitely long) nanowire where the Majorana end states do not overlap (εm = 0), the thermoelectrical conductance L in the weak-coupling regime exhibits a peak at T m. This peak is ascribed to the anti-Fano resonance between the asymmetric Kondo resonance and the zero-energy MF mode. Interestingly, in the strong-coupling regime, the Kondo-induced peak in L is shifted due to the MF-induced Zeeman splitting in the dot. For finite but small εm > 0, the interference between two MFs restores the Kondo effect in the dot in a smaller energy scale m and gives rise to an additional peak in L at T m, whose sign is opposite to that at Tm. In the strong-coupling regime this additional peak can cause a non-monotonic behavior of L with respect to the dot gate. Finally, we examine the case in which an ordinary spin-polarized fermion is coupled to the dot and identify the fingerprint of MFs by comparing two cases.