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CMB as a dark energy probe Carlo Baccigalupi. Outline  Fighting against a cosmological constant  Parametrizing cosmic acceleration  The CMB role in.

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Presentation on theme: "CMB as a dark energy probe Carlo Baccigalupi. Outline  Fighting against a cosmological constant  Parametrizing cosmic acceleration  The CMB role in."— Presentation transcript:

1 CMB as a dark energy probe Carlo Baccigalupi

2 Outline  Fighting against a cosmological constant  Parametrizing cosmic acceleration  The CMB role in the current dark energy bounds  “Classic” dark energy effects on CMB  “Modern” CMB relevance for dark energy: the promise of lensing  Lensing B modes in CMB polarization  Future CMB data and dark energy

3 Fighting the cosmological constant G µν =8πT µν

4 Fighting the cosmological constant G µν +Λg µν =8πT µν +Vg µν geometry quantum vacuum

5 Fighting the cosmological constant Λ:???

6 Fighting the cosmological constant Λ:??? V:M 4 Planck ???

7 Fighting the cosmological constant Λ:??? V:M 4 Planck ??? |Λ-V|/M 4 Planck ≲10 -123

8 Fighting the cosmological constant Λ:??? V:M 4 Planck ??? |Λ-V|/M 4 Planck =10 -123 percent precision

9 (Boh?) 2  Why so small with respect to any other known energy scale in physics?  Why comparable to the matter energy density today?

10 z Energy density 10 4 0.5 matter radiation Dark energy

11 z Energy density 10 4 0.5 matter radiation Dark energy Einstein 1916

12 z Energy density 10 4 0.5 matter radiation Dark energy Ratra & Peebles, 1988

13 z Energy density 10 4 0.5 matter radiation Dark energy Wetterich 1988

14 z Energy density 10 4 0.5 matter radiation Dark energy

15 z Energy density 10 4 0.5 matter radiation Parametrizing cosmic acceleration is … ρ (z)

16 z Energy density 10 4 0.5 matter radiation …parametrizing cosmic density ρ ∝ (1+z) 3[1+w] constant w

17 z Energy density 10 4 0.5 Parametrizing cosmic density ρ ∝ exp{3∫ 0 z [1+w(z)]dz/(1+z)} variable w

18 a=1/(1+z) w 0.51 Parametrizing cosmic acceleration: modeling w=w 0 -w a (1-a)=w 0 +(1-a)(w ∞ -w 0 ) w0w0 -w a w∞w∞ Chevallier & Polarski 2001, Linder 2003

19 a=1/(1+z) w 0.51 Parametrizing cosmic acceleration: binning Crittenden & Pogosian 2006, Dick et al. 2006

20 Parametrizing cosmic acceleration: binning versus modeling  Binning: model independent, many parameters   Modeling: always a bias , but a minimal model exists, made by w 0 and its first time derivative  Sticking with one particular model in between may be inconvenient, better relating that to one of the two approaches above

21 a=1/(1+z) w 0.51 Present cosmological bounds: one bin See Spergel et al., 2006, and references therein -1+10% -1-10% CMB Large scale structure

22 a=1/(1+z) w 0.51 Present cosmological bounds: one bin, or maybe two Seljak et al. 2005 -1+10% -1-10% CMB Large scale structure

23 “Classic” dark energy effects on CMB: projection D= H 0 -1 dz [Σ i Ω i (1+z) 3(1+w i ) ] 1/2 ∫ 0 z w D

24 “Classic” dark energy effects on CMB: integrated Sachs-Wolfe Cosmological friction for cosmological perturbations ∝H w ρ H

25 z Energy density 10 4 0.5 matter radiation The “modern” era

26 z Energy density 10 4 0.5 The “modern” era Dark energy matter equivalence CMB last scattering Matter radiation equivalence 10 3 Dark energy domination

27 z Energy density 10 4 0.5 The “modern” era Dark energy matter equivalence CMB last scattering Matter radiation equivalence 10 3 Dark energy domination

28 The “modern” era: study the signatures of structure formation on the CMB  Beat cosmic variance by predicting the ISW effect from local and observed structures  Study lensed CMB

29 The “modern” era: study the signatures of structure formation on the CMB  Beat cosmic variance by predicting the ISW effect from local and observed structures  Study lensed CMB

30 z Energy density 10 4 0.5 matter radiation The promise of lensing

31 z Energy density 10 4 0.5 matter radiation The promise of lensing

32 z Energy density 0.5 The promise of lensing 11.5

33 z Energy density 0.5 matter The promise of lensing

34  By geometry, the lensing cross section is non-zero at intermediate distances between source and observer  In the case of CMB as a source, the lensing power peaks at about z=1  Any lensing power in CMB anisotropy must be quite sensitive to the expansion rate at the onset of acceleration Lensing probability z1

35 z Energy density 0.5 The promise of lensing 11.5

36 How lensing modifies the CMB  Most relevant on the angular scales subtended by lenses, from the arcminute to the degree  It makes the CMB non-Gaussian  It smears acoustic peaks  It activates a broad peak in the B modes of CMB polarization Seljak & Zaldarriaga 1997, Spergel & Goldberg 1999, Hu 2000, Giovi et al. 2005

37 How lensing modifies the CMB  Most relevant on the angular scales subtended by lenses, from the arcminute to the degree  It makes the CMB non-Gaussian  It smears out acoustic peaks  It activates a broad peak in the B modes of CMB polarization Seljak & Zaldarriaga 1997, Spergel & Goldberg 1999, Hu 2000, Giovi et al. 2005

38 CMB angular power spectrum Angle ≈ 200/ l degrees

39 Known CMB angular power spectrum: WMAP first year Angle ≈ 200/ l degrees

40 Known CMB angular power spectrum: WMAP third year Angle ≈ 200/ l degrees

41 CMB angular power spectrum Angle ≈ 200/ l degrees Primordial power Gravity waves Acoustic oscillations Reionization Lensing

42 Last scattering Forming structures - lenses E B Lensing B modes Seljak & Zaldarriaga 1998

43 Forming structures - lenses E B Lensing B modes acceleration Last scattering Seljak & Zaldarriaga 1998

44 CMB lensing: a science per se  Lensing is a second order cosmological effect  Lensing correlates scales  The lensing pattern is non-Gaussian  Statistics characterization in progress, preliminary investigations indicate an increase by a factor 3 of the uncertainty from cosmic variance Smith et al. 2006, Lewis & Challinor 2006, Lewis 2005, …

45 z Energy density 0.5 Lensing strength recording the cosmic density at the onset of acceleration 11.5

46 z Energy density 0.5 Lensing strength recording the cosmic density at the onset of acceleration 11.5 Cosmological constant

47 z Energy density 0.5 Lensing strength recording the cosmic density at the onset of acceleration 11.5 Cosmological constant

48 So let’s play…  Upgrade a Boltzmann code for lensing computation in dark energy cosmologies (Acquaviva et al. 2004 experienced doing that with cmbfast, lensing.f has to be substantially changed…)  Get lensed CMB angular power spectra for different dark energy dynamics  Look at the amplitude of lensing B modes

49 Play…  SUGRA vs. Ratra-Peebles quintessence  Check structure formation, linear perturbation growth rate, …  Perturbations and distances affected by geometry coherently…  Effects sum up in the lensing kernel Acquaviva & Baccigalupi 2005

50 Play…  TT and EE spectra: slight projection shift  BB amplitude: reflecting cosmic density at structure formation/onset of acceleration Acquaviva & Baccigalupi 2005

51 Breaking projection degeneracy Acquaviva & Baccigalupi 2005

52 Get serious…  A Fisher matrix analysis indicates that a 1%-10% measuremtent on both w 0 and w a is achievable by having lensing B modes measured on a large sky area, few arcminute resolution, micro-K noise  New relevance for searching B modes in CMB polarization?  Independent check of the efficiency of the effect ongoing… Acquaviva & Baccigalupi 2005

53 Forthcoming B modes hunters  Planck, marginal, large scale only)  EBEx, sensitivity ok for lensing B modes, north american flight in fall 2007  QUIET, sensitivity ok for lensing B modes  Clover  Brain  …  Complete list available at lambda.gsfc.nasa.gov  Beyond Einstein, Cosmic Vision…

54 Conclusions  CMB lensing sensitivity is at high redshifts  The CMB is not a probe of the dark energy density redshift average, but can reasonably put two error bars on the dark energy abundance at z=0 and 0.5  Partner to other probes for constraining the redshift behavior of the dark energy  You do not know where systematics hit more, so keep it in your toolbox

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