Leptons, Photons & the CMB

1. Leptons, Photons & the CMB Ned Wright, UCLA 16 Aug 2007

2. Nobel Prize in Physics 2006 • John Mather for the CMB Spectrum • George Smoot for the CMB anisotropy

3. COBE View of the CMB Sky

4. Two Fluids in the Early Universe • Most of the mass is dark matter • 80-90% of the density • Zero pressure • Sound speed is zero • The baryon-photon fluid • baryons are protons & neutrons = all ordinary matter • energy density of the photons is bigger than c2 times the mass density of baryons • Pressure of photons = u/3 = (1/3) c2 • Sound speed is about c/3 = 170,000 km/sec

5. “Normal” vs Conformal ST Diagram • Constant SE course is a curve on the globe but a straight line on the conformal Mercator map. • Constant speed-of-light is a curve on the “normal” space-time diagram but a straight line on the conformal diagram.

6. Traveling Sound Wave: cs = c/3

7. Stay at home Dark Matter

8. Interference at last scattering • For the wavelength illustrated [1/2 period between the Big Bang and recombination], the denser = hotter effect and potential well = cooler effect have gotten in phase. • For larger wavelengths they are still out of phase at recombination.

9. Many parameters to measure • Careful measurements of the power at various angular scales can determine the Hubble constant, the matter density, the baryon density, and the vacuum density.

10. COBE View was Blurry

11. A New Cosmology Satellite

12. Combination to remove foreground

13. QVW as RGB

14. Effects on Peak Position: lpk • Open or vacuum dominated Universes give larger distance to last scattering surface • High matter density gives smaller wavelength

15. The CMB does not imply flatness • But CMB + Ho (or other data) do imply flatness.

16. CDM is a Good Fit

17. So is “super Sandage”

18. Info from peak & trough heights • Overall Amplitude of the perturbations • Agrees with large scale structure if almost all the dark matter is COLD dark matter • Primordial power spectrum power law spectral index: n = 0.951 ± 0.017 without running index. • EPAS inflationary prediction is n = 1 • Baryon/photon and DM/baryon density ratios • b = 0.42 yoctograms/m3 = 0.4210-30 gm/cc • cdm = 1.9 yg/m3 [ ≡ h2 = /{18.8 yg/m3}]

19. Baryon & CDM densities BBNS value 5:1 Ratio

20. mh2 is known from the CMB • CMB peak heights give the actual matter density: 2.5 yoctograms per cubic meter to 8% precision. • This assumes 3 neutrino types. Ratio of matter density to relativistic density at last scattering is measured. • This means that a given m corresponds to a given Ho. The HST key project value of 728 km/sec says m is close to 0.24 but with 25% precision from the 11% uncertainty in Ho. • Values of  = mh derived from large scale structure studies are consistent with the HST Key Project Hubble constant.

21. For pc = 3kT, limits on mass • Mass 0.5 meV is relativistic now, but higher masses go slower and don’t travel as far. • For m > 550 eV, distance << clustering length.

22. From astro-ph/0501562 • Slight preference for 700 eV mass, and anything with m > 2 keV is in the CDM limit Based on WMAP 1st year results. Warm Dark Matter eliminates the excess of low-mass halos. Density is very sub-thermal but could be a sterile neutrino.

23. Active Neutrinos • Active neutrinos must have masses so small that they free-stream out of structures. • Limit on masses based only on the hot fraction of the dark matter.

24. The End of Inflation • Pure H-Z: n=1, R=0 now fails • 4 still fails, m22 is OK.

25. The Three Simplicities •  = 0 but this probably is not correct. • tot = 1: a flat Universe. • w = -1 if there is dark energy. • Note that if w = -1, the dark energy is Lorentz invariant, but if w ≠ -1 observers can measure their velocity with respect to the dark energy so the dark energy has to be a dynamical thing that will react to inhomogeneities in the Universe. Thus DE and w will be functions of space and time.

26. We should prove flatness. • The success of the flat model with w = -1 can not be used to justify assuming flatness when trying to find w and w’. • Certainly tot = 1 is simpler, but • X = 0 is simpler, no CDM is simpler & w = -1 is simpler • But the model consistent with both the CMB and SNe data moves as w is varied, and is most consistent with the Hubble constant from the HST Key Project when w is close to -1. So w can be measured using all data combined but be suspicious of priors on tot or M.

28. Can we say anything about w? • Pretty good mutual agreement of 4 datasets for w = -1 and tot =1. • This agreement is slowly lost as w moves away from -1.

29. WMAP plus LSS and BAO • The only limit on w worth noting.

30. Compare to 0701584 • A little flatter, less “phantom” support.

31. Late ISW Effect: Another test for  Potential only changes if m  1 (or in non-linear collapse, but that’s another story [Rees-Sciama effect]).

32. Potential decays at z  0.6

33. CMB-LSS correlation seen by WMAP • This late ISW effect occurs on our past light cone so the T we see is due to structures we also see. • Correlation between WMAP and LSS seen by: • Boughn & Crittenden (astro-ph/0305001) at 2.75 with hard X-ray background and 2.25 with NVSS • Nolta et al. (astro-ph/0305097) at 2 with NVSS • Afshordi et al (astro-ph/0308260) at 2.5 with 2MASS

34. 2MASS galaxies reach z = 0.1 Credit: Tom Jarrett, IPAC

35. WIDE-FIELDINFRAREDSURVEYEXPLORER I am the PI on a MIDEX called WISE, an all-sky survey in 4 bands from 3.3 to 23 m. WISE will find and study the closest stars to the Sun, the most luminous galaxies in the Universe, and also map the large-scale structure out to redshift z=1, covering the era when the late ISW effect should be generated. WISE is under construction now and scheduled to fly in late 2009.

36. Current Conclusions • Ratio of CMB amplitude to galaxy clustering amplitude constrain the typical relict speed of the dark matter to be slower than a 550 eV thermal neutrino. • Also constrain the fraction of the dark matter that is traveling much faster: limits the sum of active neutrino masses to < 1 eV. • Peak:trough:peak ratios determine the dark matter density: 2 yoctograms/m3. • Dark energy has -1.05 < w < -0.8: a boring cosmological constant?

37. Future Prospects • WMAP is entering its 7th year of data taking. • Planck will launch in late 2008. • Much better angular resolution and sensitivity • Higher frequency channels • Better knowledge of galactic dust foregrounds • Improved matter and baryon densities • Improved spectral index and curvature of the primordial power spectrum • Thermal Sunyaev-Zeldovich data on thousands of clusters

38. Papers to view: • Jeong & Smoot (ABS-S10-003 S10-127; astro-ph/0612706): a search for Cosmic Strings in the CMB map. Similar to Lo & Wright (astro-ph/0503120) but using 3 year data. None seen to date, but Planck will greatly improve this search. • Hayashi etal, (ABS-S10-002 S10-108; astro-ph/0609657): inflation model consistent with the WMAP n = 0.951 ± 0.017