Early Universe Thermodynamics and Evolution in Nonviscous and Viscous Strong and Electroweak Epochs: Possible Analytical Solutions

Simple Summary In the early Universe, both QCD and EW eras play an essential role in laying seeds for nucleosynthesis and even dictating the cosmological large-scale structure. Taking advantage of recent developments in ultrarelativistic nuclear experiments and nonperturbative and perturbative lattice simulations, various thermodynamic quantities including pressure, energy density, bulk viscosity, relaxation time, and temperature have been calculated up to the TeV-scale, in which the possible influence of finite bulk viscosity is characterized for the first time and the analytical dependence of Hubble parameter on the scale factor is also introduced. Abstract Based on recent perturbative and non-perturbative lattice calculations with almost quark flavors and the thermal contributions from photons, neutrinos, leptons, electroweak particles, and scalar Higgs bosons, various thermodynamic quantities, at vanishing net-baryon densities, such as pressure, energy density, bulk viscosity, relaxation time, and temperature have been calculated up to the TeV-scale, i.e., covering hadron, QGP, and electroweak (EW) phases in the early Universe. This remarkable progress motivated the present study to determine the possible influence of the bulk viscosity in the early Universe and to understand how this would vary from epoch to epoch. We have taken into consideration first- (Eckart) and second-order (Israel–Stewart) theories for the relativistic cosmic fluid and integrated viscous equations of state in Friedmann equations. Nonlinear nonhomogeneous differential equations are obtained as analytical solutions. For Israel–Stewart, the differential equations are very sophisticated to be solved. They are outlined here as road-maps for future studies. For Eckart theory, the only possible solution is the functionality, H(a(t)), where H(t) is the Hubble parameter and a(t) is the scale factor, but none of them so far could to be directly expressed in terms of either proper or cosmic time t. For Eckart-type viscous background, especially at finite cosmological constant, non-singular H(t) and a(t) are obtained, where H(t) diverges for QCD/EW and asymptotic EoS. For non-viscous background, the dependence of H(a(t)) is monotonic. The same conclusion can be drawn for an ideal EoS. We also conclude that the rate of decreasing H(a(t)) with increasing a(t) varies from epoch to epoch, at vanishing and finite cosmological constant. These results obviously help in improving our understanding of the nucleosynthesis and the cosmological large-scale structure.

[1]  M. Abramowitz,et al.  Handbook of Mathematical Functions, with Formulas, Graphs, and Mathematical Tables , 1966 .

[2]  J. Aumont,et al.  Planck2018 results , 2018, Astronomy & Astrophysics.

[3]  T. Harko,et al.  Viscous quark‐gluon plasma in the early universe , 2010, 1001.2814.

[4]  G. S. Averichev,et al.  Constraining the initial conditions and temperature dependent viscosity with three-particle correlations in Au+Au collisions , 2017, Physics Letters B.

[5]  T. Harko,et al.  Viscous dissipative Chaplygin gas dominated homogenous and isotropic cosmological models , 2008, 0801.2008.

[6]  R. B. Barreiro,et al.  Planck 2018 results , 2020, Astronomy & Astrophysics.

[7]  U. Heinz,et al.  The viscosity of quark-gluon plasma at RHIC and the LHC , 2011, 1108.5323.

[8]  T. Harko,et al.  Quark-hadron phase transitions in the viscous early universe , 2011, 1108.5697.

[9]  C. A. Oxborrow,et al.  Planck2015 results , 2015, Astronomy & Astrophysics.

[10]  E. A. Milne,et al.  Newtonian Universes and the Curvature of Space , 2000 .

[11]  Thermodynamics in the viscous early universe , 2010 .

[12]  Abdel Nasser Tawfik Influence of strange quarks on the QCD phase diagram and chemical freeze-out , 2005 .

[13]  Abdel Nasser Tawfik,et al.  Bulk and shear viscosity in Hagedorn fluid , 2010, 1005.3946.

[14]  Alexander Shalyt-Margolin,et al.  Entropy in the Present and Early Universe: New Small Parameters and Dark Energy Problem , 2009, Entropy.

[15]  J. Stewart,et al.  Thermodynamics of nonstationary and transient effects in a relativistic gas , 1976 .

[16]  Milton Abramowitz,et al.  Handbook of Mathematical Functions with Formulas, Graphs, and Mathematical Tables , 1964 .

[17]  Carl Eckart,et al.  The Thermodynamics of Irreversible Processes. I. The Simple Fluid , 1940 .

[18]  Dissipative Processes in the Early Universe: Bulk Viscosity , 2009, 0911.4105.

[19]  E. A. Milne A Newtonian Expanding Universe , 2000 .

[20]  Birgit Wirtz,et al.  Principles Of Physical Cosmology , 2016 .

[21]  New forms of QCD matter discovered at RHIC , 2004, nucl-th/0405013.

[22]  M. Stephanov,et al.  Mapping the phases of quantum chromodynamics with beam energy scan , 2019, Physics Reports.

[23]  R. B. Barreiro,et al.  Planck 2018 results , 2019, Astronomy & Astrophysics.

[24]  A. Coley,et al.  Qualitative analysis of viscous fluid cosmological models satisfying the Israel-Stewart theory of irreversible thermodynamics , 1995, gr-qc/9605061.

[25]  S. Jeon,et al.  Effects of bulk viscosity and hadronic rescattering in heavy ion collisions at energies available at the BNL Relativistic Heavy Ion Collider and at the CERN Large Hadron Collider , 2018 .

[26]  L. Lindblom,et al.  Stability and causality in dissipative relativistic fluids , 1983 .

[27]  W. Israel Nonstationary irreversible thermodynamics: A Causal relativistic theory , 1976 .

[28]  Ø. Grøn Viscous inflationary universe models , 1990 .

[29]  R. Blandford Structure and Evolution of the Universe , 1998 .

[30]  E. A. Milne A Newtonian Expanding Universe , 2000 .

[31]  M. Meyer,et al.  Standard Model thermodynamics across the electroweak crossover , 2015, 1503.04935.

[32]  Z. Fodor,et al.  Calculation of the axion mass based on high-temperature lattice quantum chromodynamics , 2016, Nature.

[33]  W. Zimdahl,et al.  Bulk viscous cosmology with causal transport theory , 2011, 1103.1328.

[34]  R. B. Barreiro,et al.  Planck 2018 results , 2018, Astronomy & Astrophysics.

[35]  T. Harko,et al.  Hubble parameter in QCD Universe for finite bulk viscosity , 2010, 1008.0971.

[36]  G. S. Averichev,et al.  Energy Dependence of Moments of Net-proton Multiplicity Distributions at RHIC , 2013, 1309.5681.

[37]  Werner Israel,et al.  Thermo-field dynamics of black holes☆ , 1976 .

[38]  J. Aumont,et al.  Planck2018 results , 2013, Astronomy & Astrophysics.

[39]  Abdel Nasser Tawfik,et al.  Thermodynamics of viscous matter and radiation in the early universe , 2011, 1109.6469.

[40]  Abdel Nasser Tawfik,et al.  Effects of quantum gravity on the inflationary parameters and thermodynamics of the early universe , 2012, 1208.5655.

[41]  U. Helsinki,et al.  Standard model cross-over on the lattice , 2015, 1508.07161.

[42]  Abdel Nasser Tawfik,et al.  Equation of state for cosmological matter at and beyond QCD and electroweak eras , 2019, Journal of Physics G: Nuclear and Particle Physics.

[43]  Surajit Chattopadhyay Israel-Stewart Approach to Viscous Dissipative Extended Holographic Ricci Dark Energy Dominated Universe , 2016, 1604.05297.

[44]  Byung Chan Eu,et al.  Thermodynamics of Irreversible Processes , 1995 .

[45]  C. Misner The Isotropy of the universe , 1968 .

[46]  Edward J. Wollack,et al.  FIVE-YEAR WILKINSON MICROWAVE ANISOTROPY PROBE OBSERVATIONS: COSMOLOGICAL INTERPRETATION , 2008, 0803.0547.

[47]  A. Tawfik The Hubble parameter in the early universe with viscous QCD matter and finite cosmological constant , 2011, 1102.2626.

[48]  T. Osada Modification of Eckart theory of relativistic dissipative fluid dynamics by introducing extended matching conditions , 2011, 1111.1276.

[49]  M. Laine,et al.  Quark mass thresholds in QCD thermodynamics , 2006, hep-ph/0603048.

[50]  Levy Stable Law Description of the Intermittent Behavior in Pb+Pb Collisions at 158 AGeV/c , 2000, hep-ph/0012008.

[51]  Abdel Nasser Tawfik,et al.  Bulk viscosity at high temperatures and energy densities , 2019 .