Evolution of galaxies and dark matter halos Yipeng Jing Shanghai Astronomical Observatory Main...
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Evolution of galaxies and dark matter halos Yipeng Jing Shanghai Astronomical Observatory Main Collaborators: Chunyan Jiang ( 姜姜姜) , Cheng Li 姜姜姜 () , Donghai Zhao 姜姜姜姜 () , Lan Wang 姜姜姜 () …… .
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Taken-away conclusions The mass accretion history and the structure evolution of halos established by Zhao et al. (2009) is universally valid not only for LCDM, but also for WDM, HDM (Zhao et al. 2012); A reliable stellar mass-halo mass is directly measured from SDSS, putting useful constraints both on galaxy formation and on cosmology (Li, Cheng et al. 2012); The merger time scale of galaxies is about two times longer than previously thought ( Jiang et al. 2008); Merger leading to a increase of % in stellar mass of massive galaxies (Wang & YPJ 2010) from z=1 to z=0, consistent with our recent analysis of CFHT data (YPJ 2012)
Transcript of Evolution of galaxies and dark matter halos Yipeng Jing Shanghai Astronomical Observatory Main...
Evolution of galaxies and dark matter halos
Yipeng JingShanghai Astronomical Observatory
Main Collaborators:Chunyan Jiang (姜春艳) , Cheng Li(李成) , Donghai Zhao(赵东海) , Lan Wang (王岚)…… .
Taken from S. Faber
Theoretical framework for understanding evolution of galaxies and dark matter halos
Taken-away conclusions• The mass accretion history and the structure evolution of
halos established by Zhao et al. (2009) is universally valid not only for LCDM, but also for WDM, HDM (Zhao et al. 2012);
• A reliable stellar mass-halo mass is directly measured from SDSS, putting useful constraints both on galaxy formation and on cosmology (Li, Cheng et al. 2012);
• The merger time scale of galaxies is about two times longer than previously thought ( Jiang et al. 2008);
• Merger leading to a increase of 50-100% in stellar mass of massive galaxies (Wang & YPJ 2010) from z=1 to z=0, consistent with our recent analysis of CFHT data (YPJ 2012)
The universal mass accretion history of dark matter haloes
N-body cosmological simulations
• Assumption: MAHs are well simulated with pure dark matter (incomplete, 1024**3)
model ni Γ σ8 Ω0 Λ0 Np L NNQ η zi
SF1 1 K cut 1 1 0 5123 160 512 0.016 1481.3
SF2 0 1 1 0 5123 160 512 0.016 363.2
SF3 -1 1 1 0 5123 160 512 0.016 75.0
SF4 -2 1 1 0 5123 160 512 0.016 11.3
LCDM1 1 0.2 0.9 0.3 0.7 2563 25 512 0.0025 72
LCDM2 1 0.2 0.9 0.3 0.7 5123 100 512 0.01 72
LCDM3 1 0.2 0.9 0.3 0.7 5123 300 512 0.03 36
OCDM1 1 0.2 1.0 0.3 0 2563 50 256 0.02 72
SCDM1 1 0.5 0.55 1 0 2563 25 512 0.0025 72
SCDM2 1 0.5 0.55 1 0 5123 100 256 0.02 72
Choosing proper variables for modeling
• Given cosmology and power spectrum, after extrapolated linearly to z=0,
linear mass variance of given volume σ is determined by M, and
linear critical collapse overdensity δc by z.
Growth rate as a function of scaled “mass”
D.H. Zhao et al. (2010)
Universal differential relation w-p determines
growth rate of halo of mass M
D.H. Zhao, et al. ApJ (2009)
• LCDM
Much more accurate than van den Bocsh (2002) or Wecshler et al. (2002)
– SCDM & OCDM
Another universal correlationt: universe age
of final halo t0.03: universe
age when main progenitor mass is 4% of final halo massImportant Finding!
Evolution of halo density profile• Combined with
MAHs model we presented in part I, c-t correlation can be used to predict the evolution of halo density profile
– LCDM1-3
Evolution of halo density profile
– SCDM1-3
Prada et al. (2012) does not work!
Zhao et al. (2009) for HDM, without any tuning the parameters, universal indeed
Zhao et al. (2009) for Warm DM, without any tuning the parameters, universal indeed (Zhao et al. 2012)
Taken from S. Faber
Relation between the stellar mass of the central galaxy and host dark matter halo
Group catalog of SDSS DR7 (Yang et al. 2008)
Sky coverage: 4514 deg^2
Galaxies with redshifts: 369447 (408119)
Groups selected: 301237 (300049)
Measure the redshift cross correlation function for groups with a given central stellar mass (Li et al. 2012
Velocity dispersion – stellar mass relation
Halo mass-stellar mass relation
Luminosity – halo mass relation
Velocity dispersion – stellar mass relation
Constraint on cosmology
Sigma_8=0.88 \pm 0.04
Consistent with WMAP7 <2sigma
Taken from S. Faber
Galaxy merger timescale
Using ln(m_h/m_sub) for Coulomb logarithm (c.f. Navarro et al. (1994)
Predicted friction timescale
Measured merger timescale
repeated Navarro et al. 1994
But our conclusion is different from theirs
Fitting formula
Merger timescale for all mergers
arXiv:1204.6319
Summary• The Chandrasekhar formula, as is usually used,
under(over)-estimates merger time for minor(major) mergers ;
• If the Coulomb logarithm is replaced ln(1+lambda), the mass dependence is accounted for correctly; but underestimate
• The dependence on the circularity is much weaker than the 0.78 power;
• We have presented a fitting formula and circularity distribution which are sufficient for modeling the merger rate;
• the scatters are 40%
Evolution of the stellar mass and halo mass relation with Halo Occupation Model
• Halo (and subhalo) catalog from an high resolution N-body simulation
• Galaxies in halos (central) and subhalos (satellites) are determined by the host halos at infall (Lan Wang et al. 2006),
Using the mass functions and correlation functions from SDSS and VVDS (z=0.8)Linear interpolationUnified model
Jing & Suto (2000)
HOD method: assuming N galaxies in halo of mass M;
First applied to Las Campanas Redshift survey ,getting alpha =0.09
Jing, Mo, Boerner 1998, ApJ, 494, 1
Fitting to SDSS (Wang & YPJ 2010)
Fitting to VVDS
The stellar mass –halo mass relation
Stellar mass functions at high redshift
How many mergers
CFHT and COSMOS (preliminary)
Remarks
• Well understood for the evolution of dark matter halos
• Still very poorly for evolution of galaxies• Combining deep catalogs of galaxies with
the dark matter model can yield important clues to the evolution of galaxies
