Self-consistent conversion of a viscous fluid to particles
Abstract
Comparison of hydrodynamic and "hybrid" hydrodynamics+transport calculations to heavy-ion data inevitably requires the conversion of the fluid to particles. For dissipative fluids the conversion is ambiguous without additional theory input complementing hydrodynamics. We obtain self-consistent shear viscous phase space corrections from linearized Boltzmann transport theory for a gas of hadrons. These corrections depend on the particle species, and incorporating them in Cooper-Frye freezeout affects identified particle observables. For example, with additive quark model cross sections,proton elliptic flow is larger than pion elliptic flow at moderately high in collisions at RHIC. This is in contrast to Cooper-Frye freezeout with the commonly used "democratic Grad" ansatz that assumes no species dependence. Various analytic and numerical results are also presented for massless and massive two-component mixtures to aid the interpretation. Self-consistent viscous corrections for each species are tabulated in Appendix F for convenient inclusion in pure hydrodynamic and hybrid calculations.
Cite
@article{arxiv.1404.7850,
title = {Self-consistent conversion of a viscous fluid to particles},
author = {Denes Molnar and Zack Wolff},
journal= {arXiv preprint arXiv:1404.7850},
year = {2017}
}
Comments
Typo fixes and ambiguous language clarified, updated grant number and references, added Section IV-C with Fig. 4 as well as Section V-C with Fig. 9, Tables in Appendix G in single column journal style. (15 EPS plots, 33 pages, RevTeX style)