Critical initial-slip scaling for the noisy complex Ginzburg-Landau equation

TL;DR

This paper uses renormalization group methods to analyze the universal critical behavior of the noisy complex Ginzburg-Landau equation during early relaxation, revealing that its initial-slip exponent matches that of equilibrium model A.

Contribution

It demonstrates that the initial-slip exponent in the non-equilibrium complex Ginzburg-Landau system is identical to the equilibrium model A, supported by perturbative and spherical model analyses.

Findings

Initial-slip exponent equals that of equilibrium model A.

Universal critical behavior characterized in early relaxation stages.

Supports all-order validity through spherical model extension.

Abstract

We employ the perturbative field-theoretic renormalization group method to investigate the universal critical behavior near the continuous non-equilibrium phase transition in the complex Ginzburg-Landau equation with additive white noise. This stochastic partial differential describes a remarkably wide range of physical systems: coupled non-linear oscillators subject to external noise near a Hopf bifurcation instability; spontaneous structure formation in non-equilibrium systems, e.g., in cyclically competing populations; and driven-dissipative Bose--Einstein condensation, realized in open systems on the interface of quantum optics and many-body physics, such as cold atomic gases and exciton-polaritons in pumped semiconductor quantum wells in optical cavities. Our starting point is a noisy, dissipative Gross-Pitaevski or non-linear Schr\"odinger equation, or equivalently purely relaxational kinetics originating from a complex-valued Landau-Ginzburg functional, which generalizes the standard equilibrium model A critical dynamics of a non-conserved complex order parameter field. We study the universal critical behavior of this system in the early stages of its relaxation from a Gaussian-weighted fully randomized initial state. In this critical aging regime, time translation invariance is broken, and the dynamics is characterized by the stationary static and dynamic critical exponents, as well as an independent `initial-slip' exponent. We show that to first order in the dimensional expansion about the upper critical dimension, this initial-slip exponent in the complex Ginzburg-Landau equation is identical to its equilibrium model A counterpart. We furthermore employ the renormalization group flow equations as well as construct a suitable complex spherical model extension to argue that this conclusion likely remains true to all orders in the perturbation expansion.