Abstract
The weakly interacting Bose gas in two dimensions is considered in the dilute limit a≪1, where n is the particle density and a is the range of the potential. The standard many-body perturbation theory for this system has two separate divergences: the first, associated with classical phase fluctuations, is responsible for the vanishing of the long-range order; the second is quantum mechanical and is connected with the vanishing of the scattering t matrix at long wavelengths and low energies. An earlier diagrammatic theory of Popov, which provides a consistent description of the system in the dilute limit, is rederived heuristically from a quasiparticle picture, and also using the renormalization group. It is shown that the superfluid transition temperature is ≊4π(/2m)n/[ln ln(1/)], and the condition of validity of the dilute limit is ln ln(1/)≫1. The connection to the dilute Bose gas in dimensions d>2 and the universal behavior beyond the extreme asymptotic low-density domain are also discussed.
- Received 21 September 1987
DOI:https://doi.org/10.1103/PhysRevB.37.4936
©1988 American Physical Society