We investigate the equilibrium and nonequilibrium transport through a quantum dot in the Kondo regime, embedded between a normal metal and a topological superconductor supporting Majorana bound states at its end points. We find that the Kondo physics is significantly modified by the presence of the Majorana modes. When the Majorana modes are coupled, aside from the Kondo scale $T_K$, a new energy scale $T^{*}\ll T_K$ emerges, that controls the low-energy physics of the system. At low temperatures, the ac conductance is suppressed for frequencies below $T^{*}$, while the noise spectrum acquires a $\sim {\omega }^3$ dependence. At high temperatures, $T\gg T_K$, the regular logarithmic dependence in the differential conductance is also affected. Under nonequilibrium conditions, and in particular in the $\{T,B\}\to 0$ limit, the differential conductance becomes negative. These findings indicate that the changes in transport may serve as clues for detecting the Majorana bound states in such systems. In terms of methods used, we characterize the transport by using a combination of perturbative and renormalization-group approaches.

• Received 5 September 2014
• Revised 15 October 2014

DOI:https://doi.org/10.1103/PhysRevB.90.195108