Astroparticle physics 4. Astroparticles: rulers of the Universe? (or almost...)

1. Astroparticle physics4. Astroparticles: rulers of the Universe? (or almost...) Alberto Carramiñana Instituto Nacional de Astrofísica, Óptica y Electrónica Tonantzintla, Puebla, México alberto@inaoep.mx Xalapa, 10 August 2004

2. Planets. Stars: nuclear burning & degenerate corpses. Gas, dust (magnetic fields (cosmic-rays)). Galaxies: normal, active. Cosmological background(s). Protons, neutrons  baryons. Electrons, muons  leptons. Neutrinos. Mesons  hadrons  quarks. The composition of the Universe Early Universe / Cosmic-rays / astrophysical neutrinos / non baryonic dark matter / dark energy

3. Oort’s limit • Statistical study of motion of stars in the Solar neighborhood: first evidence of “missing mass”.

4. Dark Galactic halo • Light: • Mass: • inside solar circle • halo • extended halo Clemens (1985) 70% to 90% of the mass of the Milky Way is in the dark halo

5. MACHOs • MAssive Compact Halo Objects: • white or red dwarfes, neutron stars, black holes... • Searched (and found!)through microlensing events (Alcock et al. 1993) but • Statistics: too few MACHOs for the Galactic halo. • HST: red dwarfes < 6% of halo mass. • TeV detections of z0.03 AGN  bounds on IR background  thermal emission from MACHOs

6. Galactic rotation curves • They become flat  rigid rotation • M/L  1 consistently

7. M87 X-ray halo • M87: giant elliptical. Brightest Virgo galaxy • X-ray emission extends up to 300 kpc • thermal fre-free emission • M(300 kpc)  31013 M • M/L  750

8. Local group M31 & Milky Way M/L  50 to 70 Magellanic stream M/L  80 Groups of galaxies M/L  400h Clusters of galaxies Coma cluster   977 km/s  M(3 kpc)  3.31015 M,M/L  660 (Zwicky 1933) X-ray intracluster  M  31014 M (baryonic) cd galaxies 1013 to 1014 M,M/L 750 Local supercluster M  81014 Mh-1, M/L  400h Dynamics of groups and clusters

9. PSC-z: 15,000 galaxies from IRAS all-sky survey 2dF – 6dF: wide field spectrospic survey 2Mass: IR photometry of 30 million objects SDSS: photometric (100 million) and spectroscopic (> 1 m) HDF North & South: deep HST exposures on narrow field UDF GOODS: common HST, CXO, Spitzer fields ELAIS: from ISO Surveys of Large Scale structure of the Universe

10. PSC-z • Reshift survey for 15,000 galaxies from IRAS point source catalogue Saunders et al. 2000

11. 2dF Galaxy Survey • AAO + Cambridge + Durham + Edinburgh • 220,000 redshifts • Power spectrum of galaxy clustering up to 300 h-1 Mpc (Percival et al. 2001, +....) http://www.mso.anu.edu.au/2dFGS/

12. 6dFGs • First Data release March 2004: 52,000 redshifts (of 150,000) http://www.mso.edu.au/6DFGs/

13. Sloan Digital Sky Survey • Spectrophotometric survey of ¼ of all sky • Photometry for 100 million objects • Spectra for > 1 million objects • With a 2.5 m robotic survey telescope. • Data releases: • EDR: 14 million / 83,000 (Stoughton et al. 2002) • DR1: 53 million / 186,000 (Abazajian et al. 2003) • DR2: 88 million / 367,000 (Abazajian et al. 2004)

14. SDSS power spectrum

15. Large Scale Structure simulations • CMB = Initial conditions • Work better from CDM and 0 lss_nbody & nbody_sim movies by the Virgo Consortium 0=1, CDM M=0.3, =0 M=0.3, =0.7 Colles (1998)

16. Cosmic Microwave Background Bennett et al. 2003

17. Local to LSS to CMB

18. Distant supernovae searches • Expanding Universe • Seeking for curvature: deceleration parameter

19. High Redshift Supernova • Seeking deceleration  acceleration!

21. Cosmology standard model

22. CMB Bennett et al. 2003

23. Cmbgg OmOl CMB Slides from Max Tegmark website

24. Cmbgg OmOl CMB + LSS

25. How much dark matter is there? Cmbgg OmOl

26. How much dark matter is there? Cmbgg OmOl

27. How much dark matter is there? Cmbgg OmOl CMB

28. How much dark matter is there? . Cmbgg OmOl CMB + LSS

29. Hubble constant and total matter density Cmbgg OmOl

30. Hubble constant and total matter density Cmbgg OmOl CMB

31. Hubble constant and total matter density . Cmbgg OmOl CMB + LSS

32. Neutrino fraction Cmbgg OmOl

33. Neutrino fraction Cmbgg OmOl CMB

34. Neutrino fraction . Cmbgg OmOl CMB + LSS

35. How much dark energy is there? Cmbgg OmOl closed CMB flat + open LSS

36. Nature of the dark energy Cmbgg OmOl CMB + LSS

37. How flat is the Universe? Cmbgg OmOl CMB + LSS

38. How old is the Universe? Cmbgg OmOl CMB + LSS

39. Cmbgg OmOl CMB + LSS

40. Dark matter particles • Generate and collapse under gravity • Very weak EM coupling (WIMPs). • Categories • Hot (relativistic) VS cold (non relativistic) • Thermal relics VS non relics For a thermal relic WIMP • (1) known; (2) well motivated; (3) speculative Goldoni, astro-ph/0403064

41. 1. known: neutrinos: thermal relics too hot; CMB + LSS ruled out. 2.1 neutralinos Lighest super-sym particle of MSSM Superposition of neutral higgsinos and gauginos  weakly interactive and massive Thermal coupled relic Mass range: 40 GeV  4 TeV (WMAP) Dark matter particles

42. 2.2 axions Non thermal relics: produced by cosmic strings or vacuum alignment Photon coupling? “Useful range”: eV to meV Experimentally bounded: about to be found or to be ruled out 3. speculative self interacting dark matter particles: to solve cusp and satellite problems Almost ruled out WIMPZILLAs mass  1013 GeV Dark matter particles Goldoni, astro-ph/0403064

43. The cosmic-ray connection!? • WIMPZILLAs: produced at the end of inflation: • Stable • mean-life  age of Universe: decay beyond GZK limit

44. These presentations Available (soon!) as http://www.inaoep.mx/alberto/cursos/ap2004_1a.ppt http://www.inaoep.mx/alberto/cursos/ap2004_1b.ppt http://www.inaoep.mx/alberto/cursos/ap2004_2.ppt http://www.inaoep.mx/alberto/cursos/ap2004_3.ppt http://www.inaoep.mx/alberto/cursos/ap2004_4.ppt alberto@inaoep.mx