1 / 45

Radiation backgrounds from the first sources and the redshifted 21 cm line

Explore the background radiation from the earliest sources of the universe, including the redshifted 21 cm line, atomic cascades, and the Wouthysen-Field effect. Learn about detecting the first stars, inhomogeneous X-ray heating, and gas temperature fluctuations. This detailed overview covers ionization history, thermal evolution, coupling mechanisms, and the basics of 21 cm mapping. Discover the contributions of direct pumping and cascades in Lya production, along with the impact of X-rays on Lya generation. Dive into experimental efforts and foreground challenges in 21 cm signal detection. Gain insights into the ionization and thermal history of the universe, from the dark ages to reionization.

slucas
Download Presentation

Radiation backgrounds from the first sources and the redshifted 21 cm line

An Image/Link below is provided (as is) to download presentation Download Policy: Content on the Website is provided to you AS IS for your information and personal use and may not be sold / licensed / shared on other websites without getting consent from its author. Content is provided to you AS IS for your information and personal use only. Download presentation by click this link. While downloading, if for some reason you are not able to download a presentation, the publisher may have deleted the file from their server. During download, if you can't get a presentation, the file might be deleted by the publisher.

E N D

Presentation Transcript

  1. Radiation backgrounds from the first sources and the redshifted 21 cm line Jonathan Pritchard (Caltech) Collaborators: Steve Furlanetto (Yale) Advisor: Marc Kamionkowski (Caltech)

  2. Overview • Atomic cascades and the Wouthysen-Field Effect • Detecting the first stars through 21 cm fluctuations (Lya) • Inhomogeneous X-rayheating and gas temperature fluctuations (X-ray) • Observational prospects z~30 z~12

  3. Ionization history • Gunn-Peterson Trough Becker et al. 2005 • Universe ionized below z~6, some neutral HIat higher z • black is black • WMAP3 measurement oft~0.09 (down from t~0.17) Page et al. 2006 • Integral constraint on ionization history • Better TE measurements+ EE observations

  4. Thermal history • Lya forest Zaldarriaga, Hui, & Tegmark 2001 Hui & Haiman 2003 ?? • IGM retains short term memory of reionization - suggests zR<10 • Photoionization heating erases memory of thermal history beforereionization • CMB temperature • Knowing TCMB=2.726 K and assuming thermal coupling byCompton scattering followed by adiabatic expansion allows informed guess of high z temperature evolution

  5. TS Tb Tg HI TK 21 cm basics • Use CMB backlight to probe 21cm transition • HI hyperfine structure n1 11S1/2 l=21cm 10S1/2 n0 z=0 z=13 n1/n0=3 exp(-hn21cm/kTs) fobs=100 MHz f21cm=1.4 GHz • 3D mapping of HI possible - angles + frequency • 21 cm brightness temperature • 21 cm spin temperature Coupling mechanisms: Radiative transitions (CMB) Collisions Wouthuysen-Field

  6. Wouthysen-Field effect Hyperfine structure of HI 22P1/2 21P1/2 Effective for Ja>10-21erg/s/cm2/Hz/sr Ts~Ta~Tk 21P1/2 20P1/2 W-F recoils Field 1959 nFLJ Lymana 11S1/2 Selection rules: DF= 0,1 (Not F=0F=0) 10S1/2

  7. Higher Lyman series • Two possible contributions • Direct pumping: Analogy of the W-F effect • Cascade: Excited state decays through cascade to generate Lya • Direct pumping is suppressed by the possibility of conversion into lower energy photons • Ly a scatters ~106 times before redshifting through resonance • Ly n scatters ~1/Pabs~10 times before converting • Direct pumping is not significant • Cascades end through generation of Ly a or through a two photon decay • Use basic atomic physics to calculate fraction recycled into Ly a • Discuss this process in the next few slides… Pritchard & Furlanetto 2006 Hirata 2006

  8. Lyman b A3p,2s=0.22108s-1 A3p,1s=1.64108s-1 gg • Optically thick to Lyman series • Regenerate direct transitions to ground state • Two photon decay from 2S state • Decoupled from Lyman a • frecycle,b=0 Agg=8.2s-1

  9. Lyman g • Cascade via 3S and 3D levelsallows production of Lyman a • frecycle,g=0.26 • Higher transitions frecycle,n~ 0.3 gg

  10. Lyman alpha flux • Stellar contribution continuum injected • also a contribution from X-rays…

  11. X-rays and Lya production spiE-3 HI HII photoionization e- X-ray collisionalionization e- Lya excitation (fa0.8) HI Chen & Miralda-Escude 2006 Shull & van Steenberg 1985 heating

  12. Experimental efforts MWA: Australia Freq: 80-300 MHz Baselines: 10m- 1.5km PAST/21CMA: China Freq: 70-200 MHz LOFAR: Netherlands Freq: 120-240 MHz Baselines: 100m- 100km SKA: S Africa/Australia Freq: 60 MHz-35 GHz Baselines: 20m- 3000km (f21cm=1.4 GHz)

  13. Foregrounds • Many foregrounds • Galactic synchrotron (especially polarized component) • Radio Frequency Interference (RFI) e.g. radio, cell phones, digital radio • Radio recombination lines • Radio point sources • Foregrounds dwarf signal: foregrounds ~1000s K vs 10s mK signal • Strong frequency dependence Tskyn-2.6 • Foreground removal exploits smoothness in frequency and spatial symmetries

  14. Global history Furlanetto 2006 Adiabaticexpansion X-rayheating + + Comptonheating Heating expansion UV ionization + recombination HII regions X-ray ionization + recombination IGM Lya flux continuum injected • Sources: Pop. II & Pop. III stars (UV+Lya) Starburst galaxies, SNR, mini-quasar (X-ray) • Source luminosity tracks star formation rate • Many model uncertainties

  15. Ionization history zR~7t~0.07 Xi>0.1 • Models differ by factor ~10 in X-ray/Lya per ionizing photon • Reionization well underway at z<12

  16. Thermal history

  17. ZR ZT Za Z* Z30 Z~150 No 21 cm signal Collisionallycoupled regime Density Ly X-ray UV 21 cm fluctuations W-FCoupling Velocitygradient BaryonDensity Neutralfraction Gas Temperature Brightnesstemperature Cosmology Reionization X-raysources Lyasources Cosmology Twilight Dark Ages Reionization TS~Tg

  18. Angular separation? W-FCoupling Velocitygradient BaryonDensity Neutralfraction Gas Temperature • In linear theory, peculiar velocities correlate with overdensities Bharadwaj & Ali 2004 • Anisotropy of velocity gradient term allows angular separation Barkana & Loeb 2005 • Initial observations will average over angle to improve S/N

  19. ZR ZT Za Z* Z30 Z~150 No 21 cm signal Collisionallycoupled regime Density Ly X-ray UV 21 cm fluctuations W-FCoupling Velocitygradient BaryonDensity Neutralfraction Gas Temperature Brightnesstemperature Cosmology Reionization X-raysources Lyasources Cosmology Twilight Dark Ages Reionization TS~Tg

  20. Reionization Neutralfraction Gas Temperature W-FCoupling Velocitygradient Density Lya coupling saturated IGM hotTK>>Tg HII regions large Z=12.1 Z=9.2 Z=8.3 Z=7.6 Furlanetto, Sokasian, Hernquist 2003

  21. 21 cm fluctuations: Lya Neutralfraction Gas Temperature W-FCoupling Velocitygradient Density -negligible heating of IGM-tracks density IGM still mostlyneutral Lya flux varies • Lya fluctuations unimportant after coupling saturates (xa>>1) • Three contributions to Lya flux: • Stellar photons redshifting into Lya resonance • Stellar photons redshifting into higher Lyman resonances • X-ray photoelectron excitation of HI Chen & Miralda-Escude 2004 Chen & Miralda-Escude 2006

  22. d dV Fluctuations from the first stars • Fluctuations in flux from source clustering, 1/r2 law, optical depth,… • Relate Lya fluctuations to overdensities Barkana & Loeb 2005 • W(k) is a weighted average

  23. Determining the first sources da dominates source properties density bias Chuzhoy,Alvarez, & Shapiro 2006 Sources Ja,* vs Ja,X Pritchard & Furlanetto 2006 Spectra aS z=20 D=[k3P(k)/2p]1/2

  24. 21cm fluctuations: TK Neutralfraction Gas Temperature W-FCoupling Velocitygradient Density couplingsaturated IGM still mostlyneutral density + x-rays • In contrast to the other coefficients bT can be negative • Sign of bT constrains IGM temperature Pritchard & Furlanetto 2006

  25. Temperature fluctuations TS~TK<Tg Tb<0 (absorption)Hotter region = weaker absorption bT<0 TS~TK~Tg Tb~021cm signal dominated by temperature fluctuations TS~TK>Tg Tb>0 (emission) Hotter region = stronger emission bT>0

  26. d dV X-ray heating • X-rays provide dominant heating source in early universe(shocks possibly important very early on) • X-ray heating often assumed to be uniform as X-rays have long mean free path • Simplistic, fluctuations may lead to observable 21cm signal • X-ray flux -> heating rate -> temperature Mpc adiabatic index -1 Barkana & Loeb 2005

  27. Growth of fluctuations expansion X-rays Compton temperature fluctuations Heating fluctuations Fractional heating per Hubble time at z dT/ d=

  28. TK fluctuations • Fluctuations in gas temperature can be substantial • Amplitude of fluctuations contains information about IGM thermal history

  29. TK<Tg Angle averaged power spectrum TK>Tg m2 part of power spectrum Indications of TK dT dominates • Constrain heating transition • Dm2 <0 on largescales indicates TK<Tg(but can have Pdx<0)

  30. X-ray source spectra • Sensitivity to aS through peak amplitude and shape • Also through position of trough • Effect comes from fraction of soft X-rays

  31. dx dT da ? X-ray background? • X-ray background at high z is poorly constrained Extrapolating low-z X-ray:IR correlation gives: Glover & Brand 2003 • 1st Experiments might see TK fluctuations if heating late

  32. 21 cm fluctuations: z ? • Exact form very model dependent

  33. Redshift slices: Lya z=19-20 • Pure Lya fluctuations

  34. Redshift slices: Lya/T z=17-18 • Growing T fluctuationslead first to dip inDTb then to double peak structure • Double peak requiresT and Lya fluctuationsto have different scaledependence

  35. Redshift slices: T z=15-16 • T fluctuations dominate over Lya • Clear peak-trough structure visible • Dm2 <0 on largescales indicates TK<Tg

  36. Redshift slices: T/d z=13-14 • After TK>Tg , thetrough disappears • As heating continuesT fluctuations die out • Xi fluctuations willstart to become important at lower z

  37. Observations poor angular resolution foregrounds • Need SKA to probe these brightnessfluctuations • Observe scalesk=0.025-2 Mpc-1 • Easily distinguishtwo models • Probably won’t seetrough :(

  38. Conclusions • 21 cm fluctuations potentially contain much information about the first sources • Bias • X-ray background • X-ray source spectrum • IGM temperature evolution • Star formation rate • Lya and X-ray backgrounds may be probed by future 21 cm observations • Foregrounds pose a challenging problem at high z • SKA needed to observe the fluctuations described here • Will be interesting to include spin temperature fluctuationsin future simulations For more details see astro-ph/0607234 & astro-ph/0508381

  39. Extra Slides

  40. TS Tb Tg n1 11S1/2 l=21cm HI 10S1/2 n0 TK 21 cm basics • HI hyperfine structure n1/n0=3 exp(-hn21cm/kTs) • Use CMB backlight to probe 21cm transition z=0 z=13.75 fobs=94.9 MHz f21cm=1.4 GHz (KUOW) • 3D mapping of HI possible - angles + frequency

  41. 21 cm basics • 21 cm brightness temperature • 21 cm spin temperature

  42. The first sources 1000 Mpc Hard X-rays Lya 330 Mpc Soft X-rays HII 5 Mpc 0.2 Mpc z=15

  43. d dV X-ray heating • X-rays provide dominant heating source in early universe(shocks possibly important very early on) • X-ray heating often assumed to be uniform as X-rays have long mean free path • Simplistic, fluctuations may lead to observable 21cm signal • Fluctuations in JX arise in same way as Ja Mpc photo-ionization time integral

  44. Growth of fluctuations expansion X-rays Compton temperature fluctuations Heating fluctuations Fractional heating per Hubble time at z

More Related