Functional renormalization for quantum phase transitions with non-relativistic bosons

Abstract

Functional renormalization yields a simple unified description of bosons at zero temperature, in arbitrary space dimension d and for M complex fields. We concentrate on nonrelativistic bosons and an action with a linear time derivative. The ordered phase can be associated with a nonzero density of (quasi) particles n. The behavior of observables and correlation functions in the ordered phase depends crucially on the momentum kph, which is characteristic for a given experiment. For the dilute regime kph n1/d the quantum phase transition is simple, with the same ``mean field'' critical exponents for all d and M. On the other hand, the dense regime kph n1/d reveals a rather rich spectrum of features, depending on d and M. In this regime one observes for d≤ 3 a crossover to a relativistic action with second time derivatives. This admits order for d>1, whereas d=1 shows a behavior similar to the low temperature phase of the classical two-dimensional O(2M)-models.