1 / 44

Cosmological CPT Violation, Baryo/leptogenesis and CMB Polarization

Cosmological CPT Violation, Baryo/leptogenesis and CMB Polarization. Mingzhe Li Nanjing University. Outline. 1, Brief review on dark energy models, cosmological constant or dynamical dark energy, current status 2, Interacting dark energy: direct coupling :

susane
Télécharger la présentation

Cosmological CPT Violation, Baryo/leptogenesis and CMB Polarization

An Image/Link below is provided (as is) to download presentation Download Policy: Content on the Website is provided to you AS IS for your information and personal use and may not be sold / licensed / shared on other websites without getting consent from its author. Content is provided to you AS IS for your information and personal use only. Download presentation by click this link. While downloading, if for some reason you are not able to download a presentation, the publisher may have deleted the file from their server. During download, if you can't get a presentation, the file might be deleted by the publisher.

E N D

Presentation Transcript

  1. Cosmological CPT Violation, Baryo/leptogenesis and CMB Polarization Mingzhe Li Nanjing University

  2. Outline 1, Brief review on dark energy models, cosmological constant or dynamical dark energy, current status 2, Interacting dark energy: direct coupling: propagates long range force, spoils the flatness of the potential of dark energy derivative coupling: spin-dependent force, shift symmetry, guarantee the flatness of the potential, cosmological CPT violation 3, Model: Leptogenesis Anomaly for CMB 4, Conclusion

  3. Brief Review on Dark Energy Models Negative pressure Candidates: 1, Cosmological constant Cosmological constant problem!

  4. 2, Dynamical dark energy Quintessence: Flat potential Phantom: K-essence: Cannot cross -1, no-go theorem Feng, Wang & Zhang, PLB(2005);Vikman, PRD(2005);Zhao, Xia, Li, Feng & Zhang, PRD(2005); Xia, Cai, Qiu, Zhao &Zhang, IJMPD(2008) Quintom: crosses -1 Feng, Wang & Zhang, PLB(2005) Li, Feng & Zhang, JCAP(2005) ………

  5. It is important to determine w of DE by cosmological observations! Parameterization of equation of state: A) w=w_0+w_1 z (for small z) B) w=w_0+w_1 z / (1+z) (used mostly in the literature) C) w=w_0+w_1 sin(w_2 ln(a)+w_3)

  6. Current constraint on the equation of state of dark energy Quintom A Quintessence phantom Quintom B Xia, Li, Zhao, Zhang, PRD(2008) WMAP5result E. Komatsu et al., arXiv:0803.0547 Status: 1) Cosmological constant fits data well; 2) Dynamical model not ruled out; 3) Best fit value of equation of state: slightly w across -1  Quintom model

  7. Interacting Dark Energy Dynamical dark energy is expected to have interactions to the rest of the world besides the gravity. Two types of couplings: direct & derivative 1, direct coupling A. Long range force Constrained tightly! S.M. Carroll, PRL(1998) B. Instability under quantum corrections

  8. 2, derivative coupling: 1, obeys the shift symmetry which guarantees the flatness of the potential. 2, propagates spin-dependent force, short range, much weaker constraint from astrophysics PDG(2002) Violates Lorentz and CPT symmetry because cosmological CPT violation!

  9. Cosmological CPT violation and baryogenesis The universe is not symmetric between matter and antimatter We need baryogenesis Sakharov conditions for baryogenesis: • Baryon number non-conserving interaction • C and CP violations • Departure from thermal equilibrium Precondition: CPT is conserved! Cohen & Kaplan, PLB(1987)

  10. Interacting dark energy and baryogenesis A unified picture of matter-antimatter asymmetry and dark energy!

  11. Quintessence model with tracking solution Albrecht & Skordis, PRL(2000) Copeland, Liddle & Wands, PRD(1998).

  12. Bean, Hansen & Melchiorri, PRD(2001); Doran & Robbers, JCAP(2006)

  13. Comments: 1, The electroweak Sphaleron violates B+L and will make as low as 100GeV, M should be GeV 2, If M is higher, e.g., GUT scale or Planck mass scale, the generated baryon number asymmetry would be very small compared with the observation. 3, In this case, we turn to leptogenesis

  14. The Model Mingzhe Li, Jun-Qing Xia, Hong Li, Xinmin Zhang, PLB (2007)

  15. the decoupling temperature of B-L violating interaction. Sphaleron conserves B-L and converts B-L asymmetry generated above to a same order of baryon number asymmetry.

  16. Baryon isocurvature perturbation Adiabatic or isothermal: Isocurvature or entropy: In our case The fluctuation of the dark energy scalar field will induce a nonzero baryon isocurvature perturbation

  17. The quintessence model with potential Consistent with the observations!

  18. In our model of baryo/leptogenesis The CPT violation is very small, was large to generate enough baryon number asymmetry in the early universe.

  19. This CPT violation can be observed by CMB polarization experiments!

  20. The full lagrangian of photons The action integral is gauge invariant. Geometric Optics Approximation

  21. Basic equations:

  22. Polarization and Stokes parameters At the inertial frame I→ intensity Q&U→ linear polarization V→ circular polarization The polarization angle:

  23. Local Lorentz frame

  24. CPT violation induced the rotation of the polarization direction Rotation angle only depends on the difference of dark energy field at the source and the observer’s positions. Which characterize such CPT-violating effect!

  25. Observation of cosmological CPT violation through CMB experiments

  26. Without CPT violation, the correlations of TB and EB vanish In the case of homogeneous

  27. 1) Bo Feng et al., PRL 96, 221302 (2006) 2) WMAP3 only P.Cabella, Natoli & Silk, PRD (2007) 3) J.Q.Xia et al., arXiv:0710.3325 WMAP5 only 4) (WMAP Group) Komatsu et al., arXiv:0803.0547 5) J.Q.Xia et al., arXiv:0803.2350 6) J.Q.Xia et al., arXiv:0710.3325

  28. Spatial dependent rotation angle: Mingzhe Li & Xinmin Zhang, PRD(2008)

  29. This is the direct consequence of invariance of under the rotation Only the background evolution of dark energy provides CPT violation!

  30. The corrections are at the order of In the quintessence model with tracking potential, By assuming the initial fluctuation of quintessence generated from a GUT scale inflation

  31. Detection of Spatially Dependent Rotation Angle How to De-Rotate the Cosmic Microwave Background Polarization.M. Kamionkowski, arXiv:0810.1286 Constraining a spatially dependent rotation of the Cosmic Microwave Background Polarization.Yadav, Biswas, Su, Zaldarriaga,arXiv:0902.4466

  32. Conclusion • Dynamical dark energy has possible couplings besides gravity to other matter. Direct couplings are constrained tightly. Derivative couplings are more likely. • The derivative couplings violate CPT cosmologically and can explain the matter-antimatter asymmetry. • Our model of leptogenesis predicts CPT violation in the photon sector. It can be tested by CMB, current data favored nonzero rotation angle mildly. • The rotation angle is anisotropic in general. More studies in the future.

  33. Thanks!

  34. Brief review on dark energy CMB experiments

  35. SN Ia (SCP, HZT….) Accelerating Universe Dark Energy LSS (2dfGRS, SDSS…)

  36. Dark energy: negative pressure Einstein Equation:

  37. The corrections are at the order of Adiabatic perturbation The corrections can be ignored if M is above

More Related