Post on 13-Dec-2015
Baryonic signature in the large-scale clustering of SDSS quasars
Kazuhiro Yahata <yahata@utap.phys.s.u-tokyo.ac.jp>
Dept. of Phys., University of Tokyo.
Issha Kayo, Yasushi Suto, Matsubara Takahiko, Andy Connolly, Daniel Vanden Berk and others.
1
Comparison of survey volumes
Galaxy Quasar
QuickTime˛ Ç∆TIFFÅiLZWÅj êLí£ÉvÉçÉOÉâÉÄ
ǙDZÇÃÉsÉNÉ`ÉÉÇ å©ÇÈÇΩÇflÇ…ÇÕïKóvÇ≈Ç∑ÅBQuickTime˛ Ç∆
TIFFÅiLZWÅj êLí£ÉvÉçÉOÉâÉÄǙDZÇÃÉsÉNÉ`ÉÉÇ å©ÇÈÇΩÇflÇ…ÇÕïKóvÇ≈Ç∑ÅB
We can investigate > 100Mpc/h structure.
EH
・ Eisenstein & Hu matter transfer function (1998)
Theoretical matter 2PCF
zero crossing
baryon bumpQuickTime˛ Ç∆
TIFFÅiLZWÅj êLí£ÉvÉçÉOÉâÉÄǙDZÇÃÉsÉNÉ`ÉÉÇ å©ÇÈÇΩÇflÇ…ÇÕïKóvÇ≈Ç∑ÅB
+
-
B dependence
Predicted Ωb-dependence
Ωb↑・ slope↓・ zero-crossing scale↑
Λ dependence
Predicted ΩΛ-dependence
ΩΛ↑・ slope↓・ zero-crossing scale↑
We can derive constraints on Ωb and ΩΛ from these dependence.
Quasar sample selection
・ DR3 spectroscopic sample. ・ point source
・ Northern sky (80 ≦ α ≦ 300)
・ 15.0 ≦ mi,rc ≦ 19.1
・ 0.16 ≦ z ≦ 2.24
Quasar sample selection
sample
The quasar sample
NQSO = 20303
2D distribution
Mi’r
cN
redshift
2PCF
2PCF of SDSS quasars (Ωm=0.3,ΩΛ=0.7,h=0.7)
QuickTime˛ Ç∆TIFFÅiLZWÅj êLí£ÉvÉçÉOÉâÉÄ
ǙDZÇÃÉsÉNÉ`ÉÉÇ å©ÇÈÇΩÇflÇ…ÇÕïKóvÇ≈Ç∑ÅB
It seems that the baryon bump exists in quasar 2PCF.
・ binning
We derive constraints on Ωb fromSDSS QSO clustering.
Fitting Proc
Fitting procedure
・ h = 0.7, (0.6, 0.8)
・ spatially flat: Ωb + ΩΛ + Ωd =1
・ scale independent bias: bQSO(z)
→fitting parameters: Ωb , ΩΛ
・ compute 2PCF (theory and observation) for grids of Ωb and ΩΛ. at linear regime, s ≧ 10Mpc/h
・ compute χ2
z evolution
Redshift evolution
・ Light-cone effect (Hamana, et al. 1998)
・ The Kaiser effect
・ evolution of scale independent bias
All above effects are scale independent.Thus we can introduce effective quasar bias:
QuickTime˛ Ç∆TIFFÅiLZWÅj êLí£ÉvÉçÉOÉâÉÄ
ǙDZÇÃÉsÉNÉ`ÉÉÇ å©ÇÈÇΩÇflÇ…ÇÕïKóvÇ≈Ç∑ÅB
Chi2 h70
Result Δχ2
Approximate fit: 2.6Ωb + ΩΛ = 0.9
Quic
kTi
me˛
Ç∆
TIF
FÅiL
ZW
Åj êLí£
ÉvÉ
çÉO
ÉâÉ
ÄÇ
™Ç
±Ç
ÃÉsÉN
É`É
ÉÇ
å©
ÇÈÇ
ΩÇ
flÇ
…Ç
ÕïK
óvÇ
ł
∑Å
B
Contours: 68%, 95%, 99.7%
QuickTime˛ Ç∆TIFFÅiLZWÅj êLí£ÉvÉçÉOÉâÉÄ
ǙDZÇÃÉsÉNÉ`ÉÉÇ å©ÇÈÇΩÇflÇ…ÇÕïKóvÇ≈Ç∑ÅB
Chi2 h60
Δχ2 (h=0.60)
Quic
kTi
me˛
Ç∆
TIF
FÅiL
ZW
Åj êLí£
ÉvÉ
çÉO
ÉâÉ
ÄÇ
™Ç
±Ç
ÃÉsÉN
É`É
ÉÇ
å©
ÇÈÇ
ΩÇ
flÇ
…Ç
ÕïK
óvÇ
ł
∑Å
B
2.6Ωb + ΩΛ = 0.9
h-dependence is weak.
Chi2 h70
Δχ2 (h=0.70)
Quic
kTi
me˛
Ç∆
TIF
FÅiL
ZW
Åj êLí£
ÉvÉ
çÉO
ÉâÉ
ÄÇ
™Ç
±Ç
ÃÉsÉN
É`É
ÉÇ
å©
ÇÈÇ
ΩÇ
flÇ
…Ç
ÕïK
óvÇ
ł
∑Å
B
2.6Ωb + ΩΛ = 0.9
h-dependence is weak.
Chi2 h80
Δχ2 (h=0.80)
Quic
kTi
me˛
Ç∆
TIF
FÅiL
ZW
Åj êLí£
ÉvÉ
çÉO
ÉâÉ
ÄÇ
™Ç
±Ç
ÃÉsÉN
É`É
ÉÇ
å©
ÇÈÇ
ΩÇ
flÇ
…Ç
ÕïK
óvÇ
ł
∑Å
B
2.6Ωb + ΩΛ = 0.9
h-dependence is weak.
Degeneracy
Due to the huge errors of large scale bins, the zero-crossing scale is not well constrained yet.
Future data are important in improving the constraints.
The 2PCFs preferred from the current analysis.
Summary
Summary
We derived constraints on Ωb and ΩΛ fromSDSS QSO 2PCF.
The result is approximately fitted to 2.6Ωb + ΩΛ=0.9±0.1
Future quasar data will constrain the zero crossing scale well. We willbreak the degeneracy between Ωb and ΩΛ.
END
End
(Next: Dust Extinction)