Non-zero temperature transport near quantum critical points
Abstract
We describe the nature of charge transport at non-zero temperatures (T) above the two-dimensional (d) superfluid-insulator quantum critical point. We argue that the transport is characterized by inelastic collisions among thermally excited carriers at a rate of order kB T/. This implies that the transport at frequencies ω kB T/ is in the hydrodynamic, collision-dominated (or `incoherent') regime, while ω kB T/ is the collisionless (or `phase-coherent') regime. The conductivity is argued to be e2 / h times a non-trivial universal scaling function of ω / kB T, and not independent of ω/kB T, as has been previously claimed, or implicitly assumed. The experimentally measured d.c. conductivity is the hydrodynamic ω/kB T 0 limit of this function, and is a universal number times e2 / h, even though the transport is incoherent. Previous work determined the conductivity by incorrectly assuming it was also equal to the collisionless ω/kB T ∞ limit of the scaling function, which actually describes phase-coherent transport with a conductivity given by a different universal number times e2 / h. We provide the first computation of the universal d.c. conductivity in a disorder-free boson model, along with explicit crossover functions, using a quantum Boltzmann equation and an expansion in ε=3-d. The case of spin transport near quantum critical points in antiferromagnets is also discussed. Similar ideas should apply to the transitions in quantum Hall systems and to metal-insulator transitions. We suggest experimental tests of our picture and speculate on a new route to self-duality at two-dimensional quantum critical points.
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