The Power. of the Galaxy Power Spectrum. Eric Linder 13 February 2012 WFIRST Meeting, Pasadena

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Transcription:

The Power of the Galaxy Power Spectrum Eric Linder 13 February 2012 WFIRST Meeting, Pasadena UC Berkeley & Berkeley Lab Institute for the Early Universe, Korea 11

Baryon Acoustic Oscillations In the beginning... (well, 10-350,000 years after) It was hot. Normal matter was p +,e - charged interacting fervently with photons. This tightly coupled them, photon mfp << ct, and so they acted like a fluid. Density perturbations in one would cause perturbations in the other, but gravity was offset by pressure, so they couldn t grow - merely oscillated. Then swift decoupling so on the largest scales, set by the sound horizon, the perturbations were preserved. The same primordial imprints in the photon field show up in matter density fluctuations. M. White (CMB) Baryon acoustic oscillations = patterned distribution of galaxies on very large scales (~150 Mpc). Galaxy cluster size 2 2

Baryon Acoustic Oscillations Photons Baryons Name CMB acoustic peaks Baryon acoustic oscillations Scale 1 100 h -1 Mpc comoving Base amplitude 5 x 10-5 10-1 Osc. amplitude O(1) 5% Detection 10 15 /hand/sec indirect: light from <10 10 gal Scale of oscillations informs re cosmic distances. Angular separation angular distance d(z) Radial distance in z expansion rate H(z) Cosmic volume surveys can measure d to <1%, H to <1.5% 3 3

BAO Systematics Nonlinear, biasing effects distort BAO scale. Not a pure geometric probe depends on early evolution thru sound horizon (N eff, Ω EDE ), late evolution thru gravity (G eff (k,z), coupling). Adds to, does not substitute for, supernova distances. N. Padmanabhan++ No such thing as pure BAO: velocity distortions always affect signal extraction (even if ignore). Think in terms of full galaxy power spectrum. 4 4

Cosmic Structure Galaxy 3D distribution or power spectrum contains information on: Growth - evolving amplitude Matter/radiation density, H - peak turnover Distances - baryon acoustic oscillations Growth rate - redshift space distortions Neutrino mass, non-gaussianity, gravity, etc. 5 5

Data, Data, Data As wonderful as the CMB is, it is 2-dimensional. Number of information modes is l(l+1) or ~10 million. BOSS (SDSS III) maps 400,000 linear modes. WFIRST will map 15 million linear modes. N. Padmanabhan conformal diagram SDSS I, II, 2dF BOSS (SDSS III) courtesy of David Schlegel WFIRST 100 million galaxies z=1-2 600,000 QSOs z=1.8-3 6 6

Greatest Scientific Problem by Dava Sobel Cosmological Revolution: From 2D to 3D CMB anisotropies to redshift surveys of density/velocity field. 77

BAO for Acceleration Acceleration can be seen directly through redshift drift. McVittie/Sandage 1962 Europe wants to build a 40m telescope to stare at quasars for 10 years and measure z to 10-10. Instead, use radial BAO of galaxies 10 10 years apart. Technique Equation Nuisance Sign z Drift H 0 w < -1/3 radial BAO s w < -1 8 8

Redshift Space Distortions Redshift space distortions (RSD) map velocity field along line of sight. Gets at growth rate f, one less integral than growth factor (like H vs d). See Weinberg talk Ω m = gravitational growth index γ [GR γ=0.55] Hume Feldman 9 9

Redshift Space Distortions Kaiser formula inaccurate Accurate RSD reconstruction Kwan, Lewis, Linder 2011 P true (k,µ)=f(kµ) P form (k,µ) 2.5 M<10 13 M 0 halos F(kµ) 0 kµ Accurate for both dark matter and biased halos. Also see Okumura, Seljak, McDonald, Desjacques 2011 ; Okumura & Jing 2011 10 10

Testing Growth vs Expansion Comparing cosmic expansion history vs. cosmic growth history is one of the major tests of the cosmological framework. If do not simultaneously fit then deviation in one biases the other, e.g. looks like non-gr or non-λ. Separate out the expansion influence on the growth gravitational growth index γ. Growth rate depends on expansion and gravity. 11

Gravity and Growth Joint fit of both acceleration and gravity, with little degeneracy: σ(γ)=0.021, correlation r <0.46 12 12

Gravity thru Time and Space Test GR thru time and scale evolution; tie to observations through modified Poisson equations: G light tests how light responds to gravity (lensing). G matter tests how matter responds to gravity (growth; γ). current +WL WFIRST P k 13 13

Discovery Space Galaxy power spectrum has information on many scales, at many redshifts. Growth rate(gravity) DE Anisotropy 14 14

Summary WFIRST galaxy redshift survey has great promise to probe gravity and expansion and growth jointly. Such data is needed to uncover the origin of cosmic acceleration and new physics. P k also measures m ν, non-gaussianity, inflation. Design survey to complement ground based P k and other probes. 15 15

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