Cosmic Microwave Background

1. Cosmic Microwave Background Acoustic Oscillations, Angular Power Spectrum, Imagingand Implications for Cosmology Carlo Baccigalupi, March 31, 2004

2. Outline… • Present: angular power • Future: Imaging • CMB cleaning • Primordial non-Gaussianity • Reionization • Lensing • …

3. The Present CMB: Measuring Angular Power

4. Before And After The First Light

5. From COBE to WMAP Courtesy of the NASA/WMAP Science Team

6. WMAP Maps 23 GHz, 0.82o , 6 mK/Nobs 33 GHz, 0.62o ,3 mK/Nobs Nobs ' 103 41 GHz, 0.49o ,2 mK/Nobs 94 GHz, 0.21o , 1.4 mK/Nobs 61 GHz, 0.33o , 1.4 mK/Nobs Courtesy of the NASA/WMAP Science Team

7. The CMB Angular Power Spctrum

8. Throwing Pebbles In The Primordial Pond Homogeneity & Isotropy + + Black Body Spectrum + Courtesy of the NASA/WMAP Science Team

9. The Sound Of The Early Universe Adiabatic Isocurvature

12. +

13. The Window On The Early Universe d T/T/dr/r 0 on all scales

14. Cosmological Parameters Basic Analysis: h, ns, k ¢dns/dk, b h2, m h2, A,  Extension: , m ,wDE, r WMAP, WMAP+ACBAR+CBI+2dF+Lyman b h2 =0.022§ 0.001,0.0224 § 0.0009 m h2 =0.14§ 0.01,0.135 +0.008 -0.009 +0.04 h=0.71§ 0.06,0.71 -0.03  =0.20§ 0.07,0.17 § 0.06 ns=0.91§ 0.06,0.93§ 0.03 +0.016 k ¢dns/dk =...,-0.031 -0.017 +0.09 A=0.9 § 0.1,0.83 -0.08

15. Extension:  WMAP+ACBAR+CBI+HST+SNIa+(H0>50 km/sec/Mpc): =1.02 § 0.02 Extension: m WMAP+ACBAR+CBI+2dF: h2=imi/93.5 eV < 0.0076´ m <0.23 eV Extension: wDE WMAP+ACBAR+CBI+HST+SNIa+2dF: wDE < -0.78 Extension: r WMAP+ACBAR+CBI+2dF+infl.cons.rel.: r < -0.71

16. Reionisation ClT/ exp(-2) on l > lrh ClT,TE,E,B boosted on l < lrh ' 0.12

17. The Future CMB: Imaging Cosmology

18. CMB Spectrum…

19. CMB Spectrum… Primordial Density Perts.: non-Gaussian? Reionization: Non-Gaussian Primordial GWs Lensing: Non-Gaussian

20. CMB Spectrum…

21. Planck According To Dodelson & Hu 2003

22. True CMB…

23. WMAP CMB…

24. True CMB…

25. Planck CMB…

26. True CMB…

27. CMBpol CMB…

28. CMB Corrupted

29. The Future CMB: Foreground Removal

30. CMB Corrupted

31. Fast Independent Component Analysis (FastICA) x=As+n, find W such that Wx=s+Wn FastICA main loop: construct W row by row Choose initial w Update through wnew=E[xg(wTx)]-wE(g’(wTx)) Compare with w. If not converged go back; if converged start up next row, keeping orthogonality

32. FastICA on Planck SimulationsMaino et al. 2002 Planck nominal performance IN OUT

33. Component Separation in Polarisation See Baccigalupi et al. 2003 for results with Planck nominal performance

34. FastICA and COBE • Perform Monte Carlo simulations to quantify the effect of noise distribution • Build Criteria to Identify Physical Components in a Heavy Noise Enviroment • Add priors to check quality and consistency of the results • Extract Cosmological Parameters and Foreground Science Maino et al. 2003

35. FastICA & COBE Maino et al. 2003 Blind Non-Blind

36. The Future CMB: Imaging Physical Cosmology

37. Primordial non-Gaussianity Y =YL+fNL(YL2-<YL2>) The simplest inflationary scenario predicts fNL' 10-1 WMAP: -58< fNL< -134 Planck forecast in progress Liguori et al. 2003

38. Imaging Reionization… 9.5 arcminutes Normal Stars in proto-galaxies 20% escape fraction d T/T CMB scattering on moving electorns t compatible with WMAP Salvaterra, Ferrara et al. 2004 in prep.

39. Dark Energy & CMB: beyond Cl s L f Giovi et al. 2003, PRD in press, astro-ph/0308118

40. CMB bispectrum L Q (W ) ´dT(W )/T alm=sQ (W )Ylm(W )dW Blm l`m`l``m``=alm al`m` al``m`` Bl l`l``=åm m` m`` (mlm`l`m``l``) alm al`m` al``m`` l f l`` l`

41. CMB bispectrum & Structure Formation L < Blm l`m`l``m`` >=0 < Blm l`m`l``m`` >0 f

42. CMB bispectrum & Structure Formation L Q (W ) =Qlss(W +dW)+QISW 'Qlss(W)+rQlss(W)¢dW QISW(W )=2s0decdr dY (r,W )/dh dW =2s0decdr[(r-rdec)/rdecr]Y(r,W) <Bl l`l``>=[(2l+1)(2l`+1)(2l``+1)/16p]1/2(0l0l`0``l``) ¢ ¢ [l(l+1)- l`(l`+1)+ l``(l``+1) ]Cl Q(l``)+Perm. D(z)=[r(zdec)-r(z)]/r(zdec)r(z)3 f Q(l)=s0dec D(z) F(z) dz F(z)=dPY/dz|k=l/r(z) PY=(3Wm0 /2)2(H0/ck)4P(k,z)(1+z)2 P(k,z)=AknT(k,z)2 Hu & White 1997, Bartelmann & Schneider 2001, Komatsu & Spergel 2001, Verde & Spergel 2002

43. CMB bispectrum & Structure Formation L z r l =2p /k=r(z3)/l z3 r(z3) l =r(z2)/l z2 r(z2) l =r(z1)/l f z1 r(z1) l-1

44. L CMB bispectrum line of sight chronology z r z!1 :super-horizon scales in a flat CDM universe, dPY/dh =0, dQ/dz! 0 horizon crossing, Y decaying linearly, dQ/dz>0 onset of acceleration, change in cosmic equation of state, Y decaying linearly, dQ/dz>0 Non-linearity, Y grows, dQ/dz<0 f z! 0, l vanishes, dQ/dz! 0 l-1

45. CMB bispectrum line of sight distribution L f Giovi et al. 2003, PRD in press, astro-ph/0308118

46. CMB bispectrum & Dark Energy L Quintessence reference models SUGRA RP f

47. CMB bispectrum & Dark Energy L Ma et al. 1999, Smith et al. 2003 f Giovi et al. 2003, PRD in press, astro-ph/0308118

48. CMB bispectrum & Dark Energy L f Giovi et al. 2003, PRD in press, astro-ph/0308118

49. CMB bispectrum & Dark Energy L f Giovi et al. 2003, PRD in press, astro-ph/0308118

50. CMB bispectrum & Dark Energy L f Giovi et al. 2003, PRD in press, astro-ph/0308118