Conductance and thermopower fluctuations in interacting quantum dots

Abstract

We model an interacting quantum dot of electrons by a Hamiltonian with random and all-to-all single particle hopping (of r.m.s. strength t) and two-particle interactions (of r.m.s. strength J). For t J, such a model has a regime exhibiting the non-quasiparticle physics of the Sachdev-Ye-Kitaev model at temperatures E coh T J, and that of a renormalized Fermi liquid at T E coh, where E coh = t2 / J. Extending earlier work has computed the mean thermoelectric properties of such a dot weakly coupled to two external leads, we compute the sample-to-sample fluctuations in the conductance and thermopower of such a dot, and describe several distinct regimes. In all cases, the effect of the SYK interactions is to reduce the strength of the sample-to-sample fluctuations. We also find that in the regime where the mean transport co-efficients are determined only by the value of J at leading order, the sample-to-sample fluctuations can be controlled by the influence of the smaller t.