Spectral function for overoccupied gluodynamics from real-time lattice simulations
Abstract
We study the spectral properties of a highly occupied non-Abelian nonequilibrium plasma appearing
ubiquitously in weak coupling descriptions of QCD matter. The spectral function of this far-fromequilibrium
plasma is measured by employing linear response theory in classical-statistical real-time lattice
Yang-Mills simulations. We establish the existence of transversely and longitudinally polarized quasiparticles
and obtain their dispersion relations, effective mass, plasmon frequency, damping rate and further
structures in the spectral and statistical functions. Our new method can be interpreted as a nonperturbative
generalization of hard thermal loop (HTL) effective theory. We see indications that our results approach
leading order HTL in the appropriate limit. The method can also be employed beyond the range of validity
of HTL.
Main Authors
Format
Articles
Research article
Published
2018
Series
Subjects
Publication in research information system
Publisher
American Physical Society
The permanent address of the publication
https://urn.fi/URN:NBN:fi:jyu-201807093495Käytä tätä linkitykseen.
Review status
Peer reviewed
ISSN
2470-0010
DOI
https://doi.org/10.1103/PhysRevD.98.014006
Language
English
Published in
Physical Review D
Citation
- Boguslavski, K., Kurkela, A., Lappi, T., & Peuron, J. (2018). Spectral function for overoccupied gluodynamics from real-time lattice simulations. Physical Review D, 98(1), 014006. https://doi.org/10.1103/PhysRevD.98.014006
License
Funder(s)
Academy of Finland
European Commission
Academy of Finland
Funding program(s)
Akatemiatutkija, SA
ERC European Research Council, H2020
Akatemiatutkijan tutkimuskulut, SA
Academy Research Fellow, AoF
ERC European Research Council, H2020
Research costs of Academy Research Fellow, AoF
Additional information about funding
We are grateful to Jürgen Berges, Jacopo Ghiglieri and Asier Piñeiro Orioli for valuable discussions and would like to thank Asier Piñeiro Orioli for sharing with us the method in Eq. (44) in a private communication. T. L. is supported by the Academy of Finland, Projects No. 267321 and No. 303756. This work is supported by the European Research Council, Grant No. ERC-2015-CoG-681707. J. P. is supported by the Jenny and Antti Wihuri Foundation. J. P. acknowledges support for travel from the Magnus Ehrnrooth Foundation. K. B. and J. P. would like to thank CERN and its Theory group for hospitality during part of this work. The authors wish to acknowledge CSC-IT Center for Science, Finland, for computational resources.
Copyright© the Authors, 2018. Published by the American Physical Society.