Theoretical developments for BAO Surveys. Takahiko Matsubara Nagoya Univ.

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Transcription:

Theoretical developments for BAO Surveys Takahiko Matsubara Nagoya Univ.

Baryon Acoustic Oscillations Photons and baryons are strongly coupled by Thomson & Coulomb scattering before photon decoupling (z > 1090) Acoustic Oscillations due to Pressure & Gravity Hu & White (2004) Scientific American

Characteristic Scale of BAO BAO stops at the photon decoupling time (z=1090) Characteristic scale: Sound Horizon How far sound waves can travel by the decoupling time

Acoustic Scale & CMB Acoustic Scale is precisely constrained by CMB power spectrum Hinshow et al. (2006) Barreiro (2009)

BAO in the Large-scale Structure BAO is encoded in the spatial clustering of galaxies Offering a standard ruler for cosmology sdec = 105 h -1 Mpc Eisenstein et al. (2005) Percival et al. (2007)

Importance of the standard ruler Having a standard ruler (candle) is extremely important in cosmology Hubble s discovery of expanding universe Cepheid variables Determination of the Hubble s constant Many standard candles (TF, FP, SB, SN) Discovery of accelerating universe Supernovae Ia

BAO as a standard ruler Having a standard ruler is extremely important in cosmology Geometry of the universe Finite or infinite? Open, flat, or closed? Expansion history <=> Energy components Nature of dark matter & dark energy Existence of dark energy is one of the most fundamental problem in Physics Origin of space and time No natural explanation known so far

BAO scale is distorted in redshift survey Example: 2D correlation function in redshift space (Linear theory) TM (2004)

Statistical tools for BAO survey Power spectrum: Fourier space Correlation function: Real space TM (2004)

Sample calculation of Fisher Matrix Fisher matrix A powerful tool for predicting how well a given survey can constrain parameters TM (2004, 2006)

Theoretical issues Linear analysis of BAO in galaxy clustering is not quantitatively satisfactory Nonlinearity in various aspects should be theoretically elucidated, otherwise the estimation of dark energy etc. would be biased Nonlinearity in dynamics Nonlinearity in redshift-space distortions Nonlinearity in halo/galaxy bias For FMOS, those issues may not be serious because of S/N, but theoretically better modeling is desirable

Nonlinearity in dynamics Nonlinear dynamics distorts the BAO signature N-body simulations Eisenstein et al. (2007) Seo et al. (2008)

Nonlinearity in redshift-space distortions Redshift-space distortions change the nonlinear effects on BAO P(k):small-scale suppressed, xi(r): degradation larger Seo et al. (2005) Eisenstein et al. (2007)

Nonlinearity in bias Effects of nonlinear (halo) bias Angulo et al. (2005) Sanchez et al. (2008)

Recent progress on theoretical modeling Nonlinear dynamics Standard perturbation theory does not give satisfactory results Developments of renormalized perturbation theories etc. However, such methods so far only works for mass density fields in real space Crocce & Scoccimarro (2008) Matarrese & Pietroni (2008)

Recent progress on theoretical modeling Application of the Lagrangian perturbation theory (LPT) LPT can naturally handle nonlinear dynamics, nonlinear redshift-space distortions, and nonlinear halo bias at the same time [TM (2008a,2008b)]

Redshift-space distortions in LPT Redshift-space distortions are linear in LPT displacement field Conceptually simpler than in Standard PT obs LOS

Halo bias and LPT Galaxy bias is not easy to handle Clustering on small scales is largely affected by galaxy biasing However, bias on large scales has been successfully modeled by analytic halo model Halo is biased in Lagrangian space Halo bias is naturally incorporated to LPT 1-halo term 2-halo term

New modeling with LPT Although LPT does not fit P(k) on small scales, it correctly reproduces nonlinear smearing effects No other such theory in redshift space TM (2008a)

New modeling with LPT Halo bias is naturally incorporated in this formulation Halo bias does not significantly change the BAO scale TM (2008b)

Summary BAO is a nearly ideal standard ruler Nonlinearity, redshift-space distortions, effects of bias should be understood Developments of a theory with Lagrangian picture Analytic method is desirable

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