Theory of the Weakly Interacting Bose Gas

TL;DR

This paper reviews theoretical methods for understanding the dilute Bose gas, including perturbative expansions, finite temperature effects, and recent calculations of the critical temperature, emphasizing effective field theory approaches.

Contribution

It provides a systematic perturbative framework for the dilute Bose gas and critically examines various theoretical approaches and recent results on critical temperature calculations.

Findings

Quantum corrections to ground state energy derived

Finite temperature effects analyzed

Recent critical temperature calculations reviewed

Abstract

We review recent advances in the theory of the three-dimensional dilute homogeneous Bose gas at zero and finite temperature. Effective field theory methods are used to formulate a systematic perturbative framework that can be used to calculate the properties of the system at T=0. The perturbative expansion of these properties is essentially an expansion in the gas parameter $\sqrt{na^3}$, where $a$ is the s-wave scattering length and $n$ is the number density. In particular, the leading quantum corrections to the ground state energy density, the condensate depletion, and long-wavelength collective excitations are rederived in and efficient and economical manner. We also discuss nonuniversal effects. These effects are higher-order corrections that depend on properties of the interatomic potential other than the scattering length, such as the effective range. We critically examine various approaches to the dilute Bose gas in equilibrium at finite temperature. These include the Bogoliubov approximation, the Popov approximation, the Hartree-Fock-Bogoliubov approximation, the $\Phi$-derivable approach, optimized perturbation theory, and renormalization group techniques. Finally, we review recent calculations of the critical temperature of the dilute Bose gas, which include 1/N-techniques, lattice simulations, self-consistent calculations, and variational perturbation theory.