A nonperturbative renormalization-group approach preserving the momentum dependence of correlation functions

We investigate the structure of Polchinski's formulation of the flow equations for the continuum Wilson effective action. Reinterpretations in terms of I.R. cutoff greens functions are given. A promising non-perturbative approximation scheme is derived by carefully taking the sharp cutoff limit and expanding in `irrelevancy' of operators. We illustrate with two simple models of four dimensional \(\lambda \varphi^4\) theory: the cactus approximation, and a model incorporating the first irrelevant correction to the renormalized coupling. The qualitative and quantitative behaviour give confidence in a fuller use of this method for obtaining accurate results.

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 \(k_B T/\hbar\). This implies that the transport at frequencies \(\omega \ll k_B T/\hbar\) is in the hydrodynamic, collision-dominated (or `incoherent') regime, while \(\omega \gg k_B T/\hbar\) is the collisionless (or `phase-coherent') regime. The conductivity is argued to be \(e^2 / h\) times a non-trivial universal scaling function of \(\hbar \omega / k_B T\), and not independent of \(\hbar \omega/k_B T\), as has been previously claimed, or implicitly assumed. The experimentally measured d.c. conductivity is the hydrodynamic \(\hbar \omega/k_B T \to 0\) limit of this function, and is a universal number times \(e^2 / h\), even though the transport is incoherent. Previous work determined the conductivity by incorrectly assuming it was also equal to the collisionless \(\hbar \omega/k_B T \to \infty\) limit of the scaling function, which actually describes phase-coherent transport with a conductivity given by a different universal number times \(e^2 / h\). 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 \(\epsilon=3-d\). 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.