Finite-frequency dynamics of vortex loops at the $^4$He superfluid phase transition

TL;DR

This paper models the finite-frequency dynamics of vortex loops at the superfluid transition in helium-4, linking fractal geometry to dynamic response and confirming theoretical scaling laws.

Contribution

It introduces a vortex loop response model using the Hausdorff fractal dimension, deriving the dynamic exponent and validating it against established scaling theories.

Findings

Power-law variation of superfluid density with frequency at transition.

Fractal dimension of vortex loops relates to dynamic exponent z.

Results agree with Fisher-Fisher-Huse scaling form.

Abstract

The finite-frequency dynamics of the $^4$He superfluid phase transition can be formulated in terms of the response of thermally excited vortex loops to an oscillating flow field. The key parameter is the Hausdorff fractal dimension $d_H$ of the loops, which affects the dynamics because the frictional force on a loop is proportional to the total perimeter $P$ of the loop, which varies as $P \sim a^{d_H}$ where $a$ is the loop diameter. Solving the 3D Fokker-Planck equation for the loop response at frequency $\omega $ yields a superfluid density which varies at $T_{\lambda}$ as $\omega^{1/(d_H -1)}$. This power-law variation with $\omega$ agrees with the scaling form found by Fisher, Fisher, and Huse, since the dynamic exponent $z$ is identified as $z = d_H-1$. Flory scaling for the self-avoiding loops gives a fractal dimension in terms of the space dimension $d$ as $d_H = (d+2)/2$, yielding $z = d/2 = 3/2$ for d = 3, in complete agreement with dynamic scaling.