Critical behavior of weakly interacting bosons: A functional renormalization group approach
Abstract
We present a detailed investigation of the momentum-dependent self-energy Sigma(k) at zero frequency of weakly interacting bosons at the critical temperature Tc of Bose-Einstein condensation in dimensions 3<=D<4. Applying the functional renormalization group, we calculate the universal scaling function for the self-energy at zero frequency but at all wave vectors within an approximation which truncates the flow equations of the irreducible vertices at the four-point level. The self-energy interpolates between the critical regime k << kc and the short-wavelength regime k >> kc, where kc is the crossover scale. In the critical regime, the self-energy correctly approaches the asymptotic behavior Sigma(k) k2 - eta, and in the short-wavelength regime the behavior is Sigma(k) k2(D-3) in D>3. In D=3, we recover the logarithmic divergence Sigma(k) ln(k/kc) encountered in perturbation theory. Our approach yields the crossover scale kc as well as a reasonable estimate for the critical exponent eta in D=3. From our scaling function we find for the interaction-induced shift in Tc in three dimensions, Delta Tc / Tc = 1.23 a n1/3, where a is the s-wave scattering length and n is the density, in excellent agreement with other approaches. We also discuss the flow of marginal parameters in D=3 and extend our truncation scheme of the renormalization group equations by including the six- and eight-point vertex, which yields an improved estimate for the anomalous dimension eta ≈ 0.0513. We further calculate the constant limk->0 Sigma(k)/k2-eta and find good agreement with recent Monte-Carlo data.
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