Shedding Light to the Dark Sides of the Universe: Cosmology from Strong Interactions

A special issue of Universe (ISSN 2218-1997). This special issue belongs to the section "Cosmology".

Deadline for manuscript submissions: closed (12 September 2020) | Viewed by 24378

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Department of Astronomy and Theoretical Physics, Lund University, 221 00 Lund, Sweden
Interests: subatomic physics; astronomy; astrophysics and cosmology; grand unification; Higgs physics; supersymmetry; electroweak physics; beyond the standard model; composite models; physical vacuum; quasiclassical gravity; cosmic inflation models; heavy-ion collisions; hard production processes
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Nuclear Physics Institute ASCR, 250 68 Rez/Prague, Czech Republic
Interests: relativistic heavy ion physics; multiparticle dynamics; quark–gluon plasma; early universe
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Special Issue Information

Dear Colleagues,

The theory of quantum chromo dynamics (QCD), an organic part of the standard model (SM) of particle physics, has been validated by many theoretical and experimental studies. Despite the notable success of QCD in collider measurements over past decades, a proper first-principle understanding of the microscopic mechanism of color confinement in the infrared regime of QCD is still widely perceived as a longstanding theoretical problem. The strongly-coupled QCD dynamics controls colored particles’ (quarks and gluons) collective motion at large spacetime separations and the formation of colorless composite states (hadrons). Whether QCD is a correct theory is a topic for continuous experimental tests, in particular, at new powerful experimental facilities such as the Large Hadron Collider (LHC), currently pushing energy and intensity limits to the furthest ever frontiers. The latter provides the crucial means for progress on a very broad range of topics, performing precision tests of QCD in extreme conditions, at high temperatures and densities.

While QCD theory and the related phenomenology aspects are being intensively studied in laboratory measurements, the possible connections of this important layer of knowledge to cosmology remain rather vague and largely unexplored. No doubt, the physical vacuum has been transformed many times throughout the lifetime of the universe, and has affected its history through a sequence of events, such as the cosmic inflation, phase transitions, and the dark energy dominated expansion. Strong interactions could play an important role in some of these cosmological events. In particular, the emergence of a new state of matter called the quark-gluon plasma at the LHC is often suggested to provide an important source of empirical knowledge to what the universe looked like in the first few moments after the Big Bang. The critical phenomena of the strong interactions and real-time dynamics of confinement have immediate connections to the actively developing research areas of cosmology, such as the physics of the QCD phase transition epoch, the hadronisation of the cosmological plasma, the growth of perturbations, and the evolution of the ground state of the universe throughout its lifespan. Progress in these areas requires a deeper look at the possible interconnections between the theoretical knowledge in quantum YM field theories and (quasi)classical gravity theory on the one hand, and the empirical knowledge from particle physics measurements and cosmological data on another.

This Special Issue aims at creating an overview of the recent progress in these directions by focusing on the novel implications of quantum chromo, or, more generally, Yang–Mills (YM) dynamics, to the physics of the early universe and critical phenomena in cosmology.

Dr. Roman Pasechnik
Prof. Dr. Michal Sumbera
Guest Editors

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Keywords

  • Strong interactions in cosmology
  • QCD vacuum
  • Dark energy
  • QCD phase transition epoch
  • Color confinement
  • Quark–gluon plasma

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Published Papers (9 papers)

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Editorial

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3 pages, 170 KiB  
Editorial
Shedding Light to the Dark Sides of the Universe: Cosmology from Strong Interactions
by Roman Pasechnik and Michal Šumbera
Universe 2022, 8(10), 545; https://doi.org/10.3390/universe8100545 - 19 Oct 2022
Viewed by 1210
Abstract
The basic aim of this Special Issue was to reflect upon the modern status of research on strong interactions and their implications in Cosmology [...] Full article

Research

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40 pages, 519 KiB  
Article
Dark Side of Weyl Gravity
by Petr Jizba, Lesław Rachwał, Stefano G. Giaccari and Jaroslav Kňap
Universe 2020, 6(8), 123; https://doi.org/10.3390/universe6080123 - 12 Aug 2020
Cited by 7 | Viewed by 3068
Abstract
We address the issue of a dynamical breakdown of scale invariance in quantum Weyl gravity together with related cosmological implications. In the first part, we build on our previous work [Phys. Rev. D2020, 101, 044050], where we found a [...] Read more.
We address the issue of a dynamical breakdown of scale invariance in quantum Weyl gravity together with related cosmological implications. In the first part, we build on our previous work [Phys. Rev. D2020, 101, 044050], where we found a non-trivial renormalization group fixed point in the infrared sector of quantum Weyl gravity. Here, we prove that the ensuing non-Gaussian IR fixed point is renormalization scheme independent. This confirms the feasibility of the analog of asymptotic safety scenario for quantum Weyl gravity in the IR. Some features, including non-analyticity and a lack of autonomy, of the system of β-functions near a turning point of the renormalization group at intermediate energies are also described. We further discuss an extension of the renormalization group analysis to the two-loop level. In particular, we show universal properties of the system of β-functions related to three couplings associated with C2 (Weyl square), G (Gauss–Bonnet), and R2 (Ricci curvature square) terms. Finally, we discuss various technical and conceptual issues associated with the conformal (trace) anomaly and propose possible remedies. In the second part, we analyze physics in the broken phase. In particular, we show that, in the low-energy sector of the broken phase, the theory looks like Starobinsky f(R) gravity with a gravi-cosmological constant that has a negative sign in comparison to the usual matter-induced cosmological constant. We discuss implications for cosmic inflation and highlight a non-trivial relation between Starobinsky’s parameter and the gravi-cosmological constant. Salient issues, including possible UV completions of quantum Weyl gravity and the role of the trace anomaly matching, are also discussed. Full article
7 pages, 256 KiB  
Article
Parton Distribution Functions and Tensorgluons
by Roland Kirschner and George Savvidy
Universe 2020, 6(7), 88; https://doi.org/10.3390/universe6070088 - 29 Jun 2020
Cited by 1 | Viewed by 2220
Abstract
We derive the regularised evolution equations for the parton distribution functions that include tensorgluons. Full article
10 pages, 313 KiB  
Article
Invisible QCD as Dark Energy
by Andrea Addazi, Stephon Alexander and Antonino Marcianò
Universe 2020, 6(6), 75; https://doi.org/10.3390/universe6060075 - 31 May 2020
Cited by 3 | Viewed by 1929
Abstract
We account for the late time acceleration of the Universe by extending the Quantum Chromodynamics (QCD) color to a S U ( 3 ) invisible sector (IQCD). If the Invisible Chiral symmetry is broken in the early universe, a condensate of dark pions [...] Read more.
We account for the late time acceleration of the Universe by extending the Quantum Chromodynamics (QCD) color to a S U ( 3 ) invisible sector (IQCD). If the Invisible Chiral symmetry is broken in the early universe, a condensate of dark pions (dpions) and dark gluons (dgluons) forms. The condensate naturally forms due to strong dynamics similar to the Nambu–Jona-Lasinio mechanism. As the Universe evolves from early times to present times the interaction energy between the dgluon and dpion condensate dominates with a negative pressure equation of state and causes late time acceleration. We conclude with a stability analysis of the coupled perturbations of the dark pions and dark gluons. Full article
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15 pages, 419 KiB  
Article
Evolution of Quasiperiodic Structures in a Non-Ideal Hydrodynamic Description of Phase Transitions
by D. N. Voskresensky
Universe 2020, 6(3), 42; https://doi.org/10.3390/universe6030042 - 7 Mar 2020
Cited by 3 | Viewed by 2321
Abstract
Various phase transitions could have taken place in the early universe, and may occur in the course of heavy-ion collisions and supernova explosions, in proto-neutron stars, in cold compact stars, and in the condensed matter at terrestrial conditions. Most generally, the dynamics of [...] Read more.
Various phase transitions could have taken place in the early universe, and may occur in the course of heavy-ion collisions and supernova explosions, in proto-neutron stars, in cold compact stars, and in the condensed matter at terrestrial conditions. Most generally, the dynamics of the density and temperature at first- and second-order phase transitions can be described with the help of the equations of non-ideal hydrodynamics. In the given work, some novel solutions are found describing the evolution of quasiperiodic structures that are formed in the course of the phase transitions. Although this consideration is very general, particular examples of quark-hadron and nuclear liquid-gas first-order phase transitions to the uniform k 0 = 0 state and of a pion-condensate second-order phase transition to a non-uniform k 0 0 state in dense baryon matter are considered. Full article
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Review

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77 pages, 2592 KiB  
Review
Cosmology from Strong Interactions
by Andrea Addazi, Torbjörn Lundberg, Antonino Marcianò, Roman Pasechnik and Michal Šumbera
Universe 2022, 8(9), 451; https://doi.org/10.3390/universe8090451 - 29 Aug 2022
Cited by 8 | Viewed by 2658
Abstract
The wealth of theoretical and phenomenological information about Quantum Chromodynamics at short and long distances collected so far in major collider measurements has profound implications in cosmology. We provide a brief discussion on the major implications of the strongly coupled dynamics of quarks [...] Read more.
The wealth of theoretical and phenomenological information about Quantum Chromodynamics at short and long distances collected so far in major collider measurements has profound implications in cosmology. We provide a brief discussion on the major implications of the strongly coupled dynamics of quarks and gluons as well as on effects due to their collective motion on the physics of the early universe and in astrophysics. Full article
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30 pages, 1286 KiB  
Review
New Physics of Strong Interaction and Dark Universe
by Vitaly Beylin, Maxim Khlopov, Vladimir Kuksa and Nikolay Volchanskiy
Universe 2020, 6(11), 196; https://doi.org/10.3390/universe6110196 - 26 Oct 2020
Cited by 30 | Viewed by 2911
Abstract
The history of dark universe physics can be traced from processes in the very early universe to the modern dominance of dark matter and energy. Here, we review the possible nontrivial role of strong interactions in cosmological effects of new physics. In the [...] Read more.
The history of dark universe physics can be traced from processes in the very early universe to the modern dominance of dark matter and energy. Here, we review the possible nontrivial role of strong interactions in cosmological effects of new physics. In the case of ordinary QCD interaction, the existence of new stable colored particles such as new stable quarks leads to new exotic forms of matter, some of which can be candidates for dark matter. New QCD-like strong interactions lead to new stable composite candidates bound by QCD-like confinement. We put special emphasis on the effects of interaction between new stable hadrons and ordinary matter, formation of anomalous forms of cosmic rays and exotic forms of matter, like stable fractionally charged particles. The possible correlation of these effects with high energy neutrino and cosmic ray signatures opens the way to study new physics of strong interactions by its indirect multi-messenger astrophysical probes. Full article
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13 pages, 910 KiB  
Review
An SU(2) Gauge Principle for the Cosmic Microwave Background: Perspectives on the Dark Sector of the Cosmological Model
by Ralf Hofmann
Universe 2020, 6(9), 135; https://doi.org/10.3390/universe6090135 - 24 Aug 2020
Cited by 6 | Viewed by 3195
Abstract
We review consequences for the radiation and dark sectors of the cosmological model arising from the postulate that the Cosmic Microwave Background (CMB) is governed by an SU(2) rather than a U(1) gauge principle. We also speculate on the possibility of actively assisted [...] Read more.
We review consequences for the radiation and dark sectors of the cosmological model arising from the postulate that the Cosmic Microwave Background (CMB) is governed by an SU(2) rather than a U(1) gauge principle. We also speculate on the possibility of actively assisted structure formation due to the de-percolation of lump-like configurations of condensed ultralight axions with a Peccei–Quinn scale comparable to the Planck mass. The chiral-anomaly induced potential of the axion condensate receives contributions from SU(2)/SU(3) Yang–Mills factors of hierarchically separated scales which act in a screened (reduced) way in confining phases. Full article
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21 pages, 513 KiB  
Review
The Equation of State of Nuclear Matter: From Finite Nuclei to Neutron Stars
by G. Fiorella Burgio and Isaac Vidaña
Universe 2020, 6(8), 119; https://doi.org/10.3390/universe6080119 - 10 Aug 2020
Cited by 31 | Viewed by 3854
Abstract
Background. We investigate possible correlations between neutron star observables and properties of atomic nuclei. In particular, we explore how the tidal deformability of a 1.4 solar mass neutron star, M1.4, and the neutron-skin thickness of 48Ca and 208Pb are [...] Read more.
Background. We investigate possible correlations between neutron star observables and properties of atomic nuclei. In particular, we explore how the tidal deformability of a 1.4 solar mass neutron star, M1.4, and the neutron-skin thickness of 48Ca and 208Pb are related to the stellar radius and the stiffness of the symmetry energy. Methods. We examine a large set of nuclear equations of state based on phenomenological models (Skyrme, NLWM, DDM) and ab initio theoretical methods (BBG, Dirac–Brueckner, Variational, Quantum Monte Carlo). Results: We find strong correlations between tidal deformability and NS radius, whereas a weaker correlation does exist with the stiffness of the symmetry energy. Regarding the neutron-skin thickness, weak correlations appear both with the stiffness of the symmetry energy, and the radius of a M1.4. Our results show that whereas the considered EoS are compatible with the largest masses observed up to now, only five microscopic models and four Skyrme forces are simultaneously compatible with the present constraints on L and the PREX experimental data on the 208Pb neutron-skin thickness. We find that all the NLWM and DDM models and the majority of the Skyrme forces are excluded by these two experimental constraints, and that the analysis of the data collected by the NICER mission excludes most of the NLWM considered. Conclusion. The tidal deformability of a M1.4 and the neutron-skin thickness of atomic nuclei show some degree of correlation with nuclear and astrophysical observables, which however depends on the ensemble of adopted EoS. Full article
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