Low temperature thermal transport at the interface of a topological insulator and a d-wave superconductor

Abstract

We consider the low-temperature thermal transport properties of the 2D proximity-induced superconducting state formed at the interface between a 3D strong topological insulator (TI) and a d-wave superconductor (dSC). This system is a playground for studying massless Dirac fermions, as they enter both as quasiparticles of the dSC and as surface states of the TI. For TI surface states with a single Dirac point, the four nodes in the interface-state quasiparticle excitation spectrum coalesce into a single node as the chemical potential, μ, is tuned from above the impurity scattering rate (|μ| 0) to below (|μ| 0). We calculate, via Kubo formula, the universal limit (T → 0) thermal conductivity, 0, as a function of μ, as it is tuned through this transition. In the large and small |μ| limits, we obtain disorder-independent, closed-form expressions for 0/T. The large-|μ| expression is exactly half the value expected for a d-wave superconductor, a demonstration of the sense in which the TI surface topological metal is half of an ordinary 2D electron gas. Our numerical results for intermediate |μ| illustrate the nature of the transition between these limits, which is shown to depend on disorder in a well-defined manner.