Large-scale structure from 2dFGRS

1. Large-scale structure from 2dFGRS John Peacock IAU 216 Sydney July 2003

2. The distribution of the galaxies 1930s: Hubble proves galaxies have a non-random distribution 1950s: Shane & Wirtanen spend 10 years counting 1000,000 galaxies by eye - filamentary patterns?

3. Results from the 2dF Galaxy Redshift Survey Target: 250,000 redshifts to B<19.45 (median z = 0.11) 250 nights AAT 4m time 1997-2002

4. Australia Joss Bland-Hawthorn Terry Bridges Russell Cannon Matthew Colless Warrick Couch Kathryn Deeley Roberto De Propris Karl Glazebrook Carole Jackson Ian Lewis Bruce Peterson Ian Price Keith Taylor BritainCarlton Baugh Shaun Cole Chris Collins Nick Cross Gavin Dalton Simon Driver George Efstathiou Richard Ellis Carlos Frenk Ofer Lahav Stuart Lumsden Darren Madgwick Steve Maddox The 2dFGRS Team Stephen Moody Peder Norberg John Peacock Will Percival Mark Seaborne Will Sutherland Helen Tadros 33 people at 11 institutions

5. 2dF on the AAT

6. 2dFGRS input catalogue • Galaxies: bJ  19.45 from revised APM • Total area on sky ~ 2000 deg2 • 250,000 galaxies in total, 93% sampling rate • Mean redshift <z> ~ 0.1, almost all with z < 0.3

7. 2dFGRS geometry ~2000 sq.deg. 250,000 galaxies Strips+random fields ~ 1x108 h-3 Mpc3 Volume in strips ~ 3x107 h-3 Mpc3 NGP SGP NGP 75x7.5 SGP 75x15 Random 100x2Ø ~70,000 ~140,000 ~40,000

9. Final 2dFGRS Sky Coverage NGP SGP Final redshift total: 221,283

10. 2dFGRS Redshift distribution • N(z) Still shows significant clustering at z < 0.1 • The median redshift of the survey is <z> = 0.11 • Almost all objects have z < 0.3.

11. Cone diagram: 4-degree wedge

13. Spectrum of inhomogeneities r x Primordial power-law spectrum (n=1?) Transfer function

14. Key scales: * Horizon at zeq : 16 (Wmh2)-1 Mpc (observe Wmh) * Free-stream length : 80 (M/eV)-1 Mpc (Wm h2 = M / 93.5 eV) * Acoustic horizon : sound speed < c/31/2 * Silk damping M sets damping scale - reduced power rather than cutoff if DM is mixed Generally assume adiabatic Transfer function Parameters: WdWbWvWneutrino h w n M

15. 2dFGRS power-spectrum results Dimensionless power: d (fractional variance in density) / d ln k Percival et al. MNRAS 327, 1279 (2001)

16. Confidence limits Wmh = 0.20 ± 0.03 Baryon fraction = 0.15 ± 0.07 ‘Prior’: h = 0.7 ± 10% & n = 1

17. Power spectrum: Feb 2001 vs ‘final’

18. Model fits: Feb 2001 vs ‘final’ Wmh = 0.20 ± 0.03 Baryon fraction = 0.15 ± 0.07 Wmh = 0.18 ± 0.02 Baryon fraction = 0.17 ± 0.06 if n = 1: or Wmh = 0.18 e1.3(n-1)

19. Conclusions from P(k) • Lack of oscillations. Must have collisionless component • CDM models work • Low density if n=1 and h=0.7 apply • possibilities for error: • Isocurvature? • W=1 plus extra ‘radiation’? • Massive neutrinos? • Scale-dependent bias? (assumed dgalsdmass)

20. Photometric recalibration Start with SuperCosmos UKST scans SDSS overlap in 33 equatorial plates: rms D = 0.09 mag ( = D SDSS-MGC ) Force uniform optical and opt-2MASS colours: rms linearity and ZP corrections 1.4% and 0.15 mag Calibration good to <1% and <0.03 mag  recalibrate APM (rms 0.14 mag)

21. 2dFGRS in COLOUR passive R magnitudes from SuperCosmos active Rest-frame colour gives same information as spectral type, h, but to higher z

24. Power spectrum and galaxy type shape independent of galaxy type within error on spectrum

25. Relation to CMB results curvature baryons total density Combining LSS & CMB breaks degeneracies: LSS measures Wmh only if power index n is known CMB measures n and Wmh3 (only if curvature is known)

26. 2dFGRS + CMB: Flatness CMB alone has a geometrical degeneracy: large curvature is not ruled out Adding 2dFGRS power spectrum forces flatness: | 1 - Wtot | < 0.04 Efstathiou et al. MNRAS 330, L29 (2002)

27. The CMB peak degeneracy

28. Detailed constraints for flat models(CMB + 2dFGRS only: no priors) Preferred model is scalar-dominated and very nearly scale-invariant Percival et al. MNRAS 337, 1068 (2002)

29. Impact of WMAP

30. likelihood contours pre-WMAP + 2dFGRS 147024 gals scalar only, flat models

31. likelihood contours post-WMAP + 2dFGRS 147024 gals scalar only, flat models - WMAP reduces errors by factor 1.5 to 2

32. likelihood contours post-WMAP + 2dFGRS 213947gals scalar only, flat models

33. Vacuum equation of state (P = w rc2) w shifts present horizon, so different Wm needed to keep CMB peak location for given h w < - 0.54 similar limit from Supernovae: w < - 0.8 overall 2dFGRS

34. Extra relativistic components? Matter-radiation horizon scale depends on matter density (Wmh2) and relativistic density (=1.68 rCMB for 3 light neutrinos). Suppose rrel = X (1.68 rCMB ) so apparent Wmh = Wmh X-1/2 and Wm=1 h=0.5 works if X=8 But extra radiation affects CMB too. Maintaining peak location needs h=0.5X1/2 if Wm=1 If w=-1, 2dFGRS+CMB measureh X-1/2 = 0.71 +- 5% with HST h = 0.72 +- 11%, hence 1.68X = 1.70 +- 0.24 (3.1 +- 1.1 neutrinos)

35. Summary • >10 Mpc clustering in good accord with LCDM • power spectrum favours Wm h= 0.18 & 17% baryons • CMB + 2dFGRS implies flatness • CMB + Flatness measures Wm h3.4 = 0.078 • hence h = 0.71 ± 5%, Wm = 0.26 ± 0.04 • No evidence for tilt (n = 0.96 +- 0.04) or tensors • But large tensor fractions not yet strongly excluded • Neutrino mass <0.6 eV if Wm =1 excluded • w < - 0.54 by adding HST data on h (agrees with SN) • Boosted relativistic density cannot save Wm =1 • Neutrino background detected if w = -1 • Data public: http://www.mso.anu.edu.au/2dFGRS/Public