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Dark Matter and Dark Energy from the solution of the strong CP problem

PART 2. Dark Matter-Baryon segregation in the non-linear evolution of coupled Dark Energy models. Roberto Mainini Universita’ di Milano Bicocca. Mainini (2005) Phys.Rev.D submitted. PART 1. Dark Matter and Dark Energy from the solution of the strong CP problem.

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Dark Matter and Dark Energy from the solution of the strong CP problem

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  1. PART 2 Dark Matter-Baryon segregation in the non-linear evolution of coupled Dark Energy models Roberto Mainini Universita’ di Milano Bicocca Mainini (2005) Phys.Rev.D submitted PART 1 Dark Matter and Dark Energy from the solution of the strong CP problem Mainini & Bonometto Phys.Rev.Lett. 93 (2004) 121301 Mainini, Colombo & Bonometto (2004) Apj accepted Roberto Mainini, L. Colombo & S.A. Bonometto Universita’ di Milano Bicocca

  2. Dual-Axion Model Axion: DM candidate from Peccei-Quinn (PQ) solution to the strong CP problem modifying PQ model : • - strong CP problem solved (even better so…) • DM and DE from single complex scalar field • (exploit better the same fields as in PQ approach) • no fine-tuning • - number of parameteras SCDM (even 1 less than LCDM…) • DM an DE in fair proportion from one parameter • - DM and DE coupled (this can be tested) but ….. • …..no extra parameter (coupling strength set by theory)

  3. Strong CP problem Non-perturbative effects related to the vacuum structure of QCD leads a CP-violating term in LQCD : Neutron electric dipole moment Experimental limits on electric dipole moment Why θ is so small?

  4. Peccei-Quinn solution and the axionPeccei & Quinn 1977 PQ idea: CP-violating term is suppressed making  a dynamical variable driven to zero by the action of its potential • Additional global U(1)PQ symmetry in SM • U(1)PQ is spontaneously broken at the scale FPQ - -parameter is now the NG boson due to sym.br. : the axion Weinberg 1978; Wilczek 1978 with NG potential

  5. - CP-violating terms generate a potential for the axion which acquires a mass m(T) (chiral symmetry break).From instantonic calculus: • FPQis a free parameter • Cosmological and astrophysical constraints require:

  6. Axion cosmology - Equation of motion (θ <<1): • Coherent oscillations for • Oscillations are damped by the expansion of the universe • Axions as Dark Matter candidate Averaging over cosmological time <Ekin> = <Epot> Kolb & Turner 1990

  7. Can a single scalar field account for both DM and DE? NG potential Tracker quintessence potential with a complex scalar field no longer constant but evolves over cosmological times PQ model Dual-Axion Model Angular oscillations are still axions whileradial motion yields DE

  8. AXION DARK ENERGY LAGRANGIAN THEORY Friction term modified: more damping than PQ case COUPLED QUINTESSENCE MODEL with a time dependent coupling C()=1/ Amendola 2000, 2003

  9. We use SUGRA potential Note: in a model with dynamical DE (coupled or uncoupled) once ΩDM is assigned  can be arbitrarily fixed. Here  is univocally determined Background evolution

  10. Background evolution coupling term settles on different tracker solution

  11. Background evolution After equivalence the kinetic energy of DE is non-negligible during matter era

  12. Axion mass Φ variation cause a dependence of the axion mass on scale factor a Rebounce at z=10 could be critical for structure formation Maccio’ et al 2004, Phys. Rev. D69, 123516

  13. Conclusions • One complex scalar field yields both DM & DE • Fair DM-DE proportions from one parameter : /GeV~1010 • Strong CP problem solved • DM-DE coupling fixed (C=1/)

  14. Dark Matter-Baryon segregation in the non-linear evolution of coupled Dark Energy models Roberto Mainini Università di Milano Bicocca

  15. Post–linear evolution of density fluctuation: The spherical “top-hat” collapse Gravitational instability: present struture (galaxy, group, cluster) originated by small density perturbation Perturbation evolution: linear theory until  << 1 But…..for present structure  >> 1 Simplest approach to non-linearity is to follow an inhomogeneity with particularly simple form

  16. Energy conservation between turn-around and virialization Virial theorem + Post–linear evolution of density fluctuation: The spherical “top-hat” collapse Top-hat overdensity in SCDM: Initial expansion with Hubble flow, then separation from background universe and collapse …as a closed FRW universe Virial radius Assuming mass conservation …. Density contrast

  17. Post–linear evolution of density fluctuation: The spherical “top-hat” collapse Top-hat overdensity in CDM and uncoupled DE models: Assuming an homogeneous DE field….. Virial radius …again from virial theorem and energy conservation but…. Density contrast no longer constant Mainini, Macciò & Bonometto 2003, New Astron., 8, 173

  18. Coupled Dark Energy (cDE) Basic equations Spatially flat FRW universe with: baryons, radiation, cold DM and DE (scalar field  with potential V()) Friedmann eq. Continuty equations: Interaction DM-DE parametrized by Usual eqs. for baryons andradiation

  19. Coupled Dark Energy Coupling effects: modified DM dynamics -Variable mass for DM particles -Violation of equivalence principle -Newtonian interactions: DM-DM particles: effective gravitational constant DM-baryons or baryons-baryons: ordinary gravitational constant

  20. Linear bias modified friction term modified source term N-body simulations indicate that the bias persists also at non-linear level Macciò, Quercellini, Mainini, Amendola & Bonometto 2004, Phys.Rev.D 69, 123516 Coupled Dark Energy (cDE) Coupling effects: DM-baryons bias From linear theory: DM and baryons density fluctuations described by 2 coupled Jeans’ equations:

  21. Spherical collapse in cDE models Start with: -DM and baryons top-hat fluctuations of identical radius RTH,i expanding with Hubble flow -Fluctuation amplitudes in DM and baryons set by linear theory: then, consider a set of n concentric shells with radii Rnc (DM) Rnb (baryons) such that and initial conditions:

  22. From T;= 0, using comoving radii and Eqs. in physical coordinates Usual Friedmann-like equation for baryon shells modified friction term modified source term Modified equation for DM shells Spherical collapse in cDE models: Time evolution of concentric shells stronger gravitational push for DM layers, also strengthened by modified friction term

  23. Spherical collapse in cDE models: Time evolution of concentric shells -DM fluctuation expands more slowly and reach turn-around earlier -Baryons contraction at different times for different layers -Baryons gradually leak out from the fluctuation bulk As a consequence….. baryon component deviates from a top-hat geometry

  24. Spherical collapse in cDE models Density profiles • - Top-hat geometry kept for DM • - Deviation from a top-hat geometry for baryons outside RTH • Perturbation also in material outside the boundary of fluctuation: • outside RTHbaryon recollapse fastened by increased density of DM

  25. Spherical collapse in cDE models: Escaped baryon fraction - Barion fraction fb outside RTH at virialization: - Mildly dependence on the scale 

  26. No virialization with all the materials of original fluctuation – and only them Virialization in cDE models - Slower gravitational infall for baryons: outer layers of halo rich of baryons - Gradually recollapse of external baryons onto the DM-richer core: DM materials outside the original fluctuation carried with them - Original DM / baryons ratio increased How to define virialization in cDE models? 1 - Only materials within top-hat considered: escaped baryon fraction neglected 2 - All materials inside original fluctuation plus intruder DM considered but……..any intermediate choice also alloweded

  27. Virialization in cDE models Our choice: 1 - Only materials within top-hat considered: escaped baryon fraction neglected Virialization condition: Kinetic and potential energies: Potential energy made of three terms: self-interaction, mutual interaction, interaction with DE DM-DE energy exchange for fluctuation described by G*=G

  28. …but different baryons layers have different growth rates not valid for Tb(RTH) Virialization in cDE models Performing integrals… Density contrast

  29. Conclusions Spherical top-hat collapse model in cDE theories: Ambiguity of definition of halo virialization: difficulty in comparing simulations outputs or data with PS or similar prediction But…indipendently of the way how virialization is defined: 1 - Only materials within top-hat considered: escaped baryon fraction neglected 2 - All the materials inside the original fluctuation plus intruder DM considered (or any intermediate choice) Final virialized system is richer of DM

  30. Conclusions DM-baryons segregation during spherical growth: a fresh approach in the treatment of a number of cosmological problems large scale: baryon enrichment of large clusters? intermediate scale: lost baryonic materials as intra-cluster light? (X-ray, EUV excess emission problem) small scale: systems likely to loose their outer layers because of close encounters with heavier objects (missing satellite problem solved?) -Simulations of DM-DE coupled cosmologies urgently required -Replacing constant coupling with 1/ coupling

  31. Fit to WMAP data Best fit parameters: -Main differences at low l - 2eff from 1.064 (uncoupled SUGRA) to 1.071 (C=1/) - SUGRA with C=1/ h=0.930.05 Uncoupled SUGRA SUGRA with C = cost SUGRA with C= 1/ SUGRA Dual-Axion

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