Superuniversal transport near a (2 + 1)-dimensional quantum critical point

Abstract

We compute the zero-temperature conductivity in the two-dimensional quantum O(N) model using a nonperturbative functional renormalization-group approach. At the quantum critical point we find a universal conductivity σ*/σQ (with σQ=q2/h the quantum of conductance and q the charge) in reasonable quantitative agreement with quantum Monte Carlo simulations and conformal bootstrap results. In the ordered phase the conductivity tensor is defined, when N≥ 3, by two independent elements, σA(ω) and σB(ω), respectively associated to O(N) rotations which do and do not change the direction of the order parameter. Whereas σA(ω 0) corresponds to the response of a superfluid (or perfect inductance), the numerical solution of the flow equations shows that ω 0σB(ω)/σQ=σB*/σQ is a superuniversal (i.e. N-independent) constant. These numerical results, as well as the known exact value σB*/σQ=π/8 in the large-N limit, allow us to conjecture that σB*/σQ=π/8 holds for all values of N, a result that can be understood as a consequence of gauge invariance and asymptotic freedom of the Goldstone bosons in the low-energy limit.