How does non-linear dynamics affect the baryon acoustic oscillation?
Abstract
We study the non-linear behavior of the baryon acoustic oscillation in the power spectrum and the correlation function by decomposing the dark matter perturbations into the short- and long-wavelength modes. The evolution of the dark matter fluctuations can be described as a global coordinate transformation caused by the long-wavelength displacement vector acting on short-wavelength matter perturbation undergoing non-linear growth. Using this feature, we investigate the well known cancellation of the high- solutions in the standard perturbation theory. While the standard perturbation theory naturally satisfies the cancellation of the high- solutions, some of the recently proposed improved perturbation theories do not guarantee the cancellation. We show that this cancellation clarifies the success of the standard perturbation theory at the 2-loop order in describing the amplitude of the non-linear power spectrum even at high- regions.We propose an extension of the standard 2-loop level perturbation theory model of the non-linear power spectrum that more accurately models the non-linear evolution of the baryon acoustic oscillation than the standard perturbation theory. The model consists of simple and intuitive parts: the non-linear evolution of the smoothed power spectrum without the baryon acoustic oscillations and the non-linear evolution of the baryon acoustic oscillations due to the large-scale velocity of dark matter and due to the gravitational attraction between dark matter particles. Our extended model predicts the smoothing parameter of the baryon acoustic oscillation peak at as and describes the small non-linear shift in the peak position due to the galaxy random motions.
Cite
@article{arxiv.1306.6660,
title = {How does non-linear dynamics affect the baryon acoustic oscillation?},
author = {Naonori S. Sugiyama and David N. Spergel},
journal= {arXiv preprint arXiv:1306.6660},
year = {2014}
}
Comments
27 pages, 8 figures