physics of the formation and evolution of galaxies physics of the formation and evolution of...
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Physics of the Formation and Evolution of Galaxies
Report from the High-z Working Group
Tsutomu T. TAKEUCHI(Nagoya University)
Hiroyuki HIRASHITA (ASIAA)Shuichiro YOKOYAMA (Nagoya University)
and members of the high-z working group
Japan SKA Workshop 2010, 4-5 Nov., 2010, NAOJ, Mitaka, Japan
Part I: Galaxy Evolution with a Wideband Receiver at 1-15 GHz
1. Overview of the Working Group2. Possible Observations3. Requirement for the Instruments4. Summary of Part I
Part II: Exploring Non-Gaussianity in the Primordial Perturbation with 21-cm Line Tomography
5. Primordial non-Gaussianity 6. The 21-cm Tomography7. Summary of Part II
Outline
Part IGalaxy Evolution with a Wideband
Receiver at 1-15 GHz
Twenty-two members in the mailing list (from students to senior researchers with wide range of expertise).
Representative: Hiroyuki HIRASHITA (ASIAA, Taiwan)
Core members: Tsutomu T. TAKEUCHI (Nagoya U.) Daisuke IONO (NAOJ) Shinki OYABU (Nagoya U.)
The high-z working group is open to anyone.If you would like to participate in this working group, please let us know.
1. Overview of the Working Group
Here we concentrate on a frequency range of 1-15 GHz, possibly contributed from Japanese instrumentation.
(1) H2O maser: 22 GHz (z > 0.5)(2) NH3 lines: 23.7 GHz (z > 0.5)(3) H I emission line: 1.4 GHz (z < 0.4)(4) CO absorption lines: z > 6.7(5) Continuum
2. Possible Observations
Possible important sciences for lower frequencies: redshifted H I: 1.4/(1 + z) GHz for cosmology (Part II)
In this talk, direct contributions from the WG members are indicated by .
100 m Effelsberg z = 2.64 (lensed: factor 35)104 L☉ (lens-corrected)
Two detections so far for z > 0.5Barvainis & Antonucci (2005): SDSS J08043+3607 @ z = 0.66Violette Impellizzeri et al. (2008): MG J0414+0534 @ z = 2.64
EVLA
n(H2) > 107 cm-3
T > 300 Kassociated with AGNenvironments (accretion disk or AGN jets)
2.1 H2O maser (22 GHz; z > 0.5)
Emission is very weak ⇒ Absorption may be better.
An example for the detection of absorption for a lensed quasar at z = 0.9 (Henkel et al. 2008)
Level population of various rotational states
⇒ We can trace the excitation temperature.
Interesting viable way to explore the state of the ISM in high-z galaxies.
2.2 NH3 lines (23.7 GHz; z > 0.5)
Baryonic Tully-Fisher relation (BTF) (McGaugh et al. 2000)
Important empirical relation connecting the halo (dynamical) mass and baryon content. Especially important for very late type galaxies (H I-dominated in baryonic content).
HIPASS result (Meyer et al. 2008):
which is steeper than luminosity TF. However, it is still too shallow.
Some recent works showed a possible downward deviation from a single power law.
2.3 H I emission (21 cm; z < 0.4)
4VM B
The “extended” BTF (McGaugh et al. 2010)
Toward lower H I masses!
The slope becomes steeper from the largest to the smallest structures (clusters: violet symbols, giant galaxies: blue symbols, and dwarf spheroidals: red symbols).
⇒ Possible effect of feedback?
However, gaseous dwarfs are missing on this plot.
2.3 H I emission (21 cm; z < 0.4)
Inoue, Omukai, & Ciardi (2007)
Probe of physical and chemical conditions in high-z ISM.1-15 GHz continuum ~ 0.1-1 mJy at tobs~10 days for z = 5-30
Molecular absorption lines in -ray burst afterglows
t vs. n, Z in protostellar clouds
expected afterglow spectra
2.4 CO absorption lines (z > 6.7)
Radio
Condon (1992)Synchrotron from supernova remnants ⇒ Related to star formation activity
> 15/(1+z) GHz is favorable to avoid f-f absorption in dense (> 103 cm-3) regions
2.5 Continuum
Synchrotron
Dust
Free-free
M82
Potentially interesting area for very young galaxies
15 GHz
Hirashita (2010)
2.5 Continuum
(1) H2O maser: peak 3 mJy (z = 2.64) with lensing factor 35 (Violette Impellizzeri et al. 2008) → 0.1 mJy
(2) NH3 → determined by the continuum level and S/N. Continuum ~ Jy (quasar) and S/N = 100 → 10 mJy
(3) H I emission: down to H I mass = 103 M☉(~ baryonic mass of dSph) → at 3 Mpc; 50 Jy (M/103M☉)/(v/10 km-s) (extended)
(4) The radio SED models suggest that absorption with ~ 1 in a GRB can be observed with a Jy-level detection limit.
3. Requirement for the Instruments
(5) Radio continuum from galaxies
Expected observed-frame 1.4 GHz flux density for galaxies of various IR luminosities assuming the FIR–radio correlation (qIR = 2.64) is shown (Murphy 2009).
N.B. Cosmic ray electrons lose energy through inverse Compton scattering of the CMB, and nonthermal continuum is strongly suppressed at high-z.
To detect moderate LIRGs at z = 4-10, the detection limit of 10 nJy is required.
(1) Lines• Can trace the evolution along redshift z• Can determine the excitation temperature and
density (e.g. CO(1-0) and CO(2-1))
(2) Continuum• Can receive a larger number of photons
Merits of wide frequency range
N.B. a special imaging technique to deal with a large dynamic range should also be developed.
⇒ Suggestions are welcome!
(1) Working group member is now composed of 22 people but should be expanded.
(2) Possible sciences for 1-15 GHz area. Lines (H2O maser, NH3 lines, H I, CO; depending on z)b. Continuum (Radio-FIR relation → collaboration with
ALMA)c. New ideas!
(3) Requirements:a. Sensitivities of m-10 nJy.b. Imaging techniques should also be developed.
4. Summary of Part I
Part IIExploring Non-Gaussianity in the
Primordial Perturbation with 21-cm Line Tomography
1. Primordial Non-Gaussianity
Now the primordial non-Gaussianity is hitting the limelight of cosmologists (Komatsu & Spergel 2001, and many others!)
CMB, LSS observations ⇒ nature of primordial fluctuations ⇒ physics of the early Universe.
• amplitude ⇔ energy scale of inflation• scale-dependence ⇔ form of the potential of inflaton• statistics⇔ standard inflation scenario?
Current observations predict that the primordial fluctuation has almost Gaussian statistics as expected from the linear perturbation theory.
1.1 Basics
2Gauss
2GaussNLGauss )()( xxfxx
Non-zero fNL gives1. Higher order contribution in the power spectrum (2-point
correlation function.)2. Leading order contribution in the bispectrum (3-point
correlation function) !!
1.2 Parameterization with fNL
Non-Gaussianity is a very broad category and until recently no systematic way to investigate it was known , in spite of enormous theoretical effort made in 90’s.
The situation has dramatically changed by the introduction of the nonlinearity parameter, fNL. The primordial perturbation F is described as
Current observational limit from WMAP 7-year data
(central value ~ 40 …??)
Future CMB observations: Planck
CL) (95% 7410 localNL f
5NL f
Theoretical predictions: • Single, slow-roll inflation model (standard inflation scenario)
( = order of slow-roll parameters ) • Non-slow-roll model, multi-scalar model
)01.0(NL Of
)11.0(NL Of
2. The 21-cm Tomography
21 cm hydrogen line: 1.4 GHz ⇒ 1.4/(1+z) GHz @redshift z
i.e.,z = 100 – 30 ⇔ 14 MHz – 47 MHz proton
electron
photon
Brightness temperature: spin temperature of H I.: optical depth for the hyperfine transition.
Fluctuation in the brightness temperature
density fluctuations of neutral gas
primordial fluctuations Loeb and Zaldarriaga (2004)
2.1 The 21-cm signal from neutral hydrogen gas
The bispectrum (Fourier transformed 3-point correlation) of the CMB brightness temperature map can be used to estimate fNL efficiently (Cooray 2006).
2.2 Bispectrum of the CMB temperature fluctuations
3D data!!
Optimistic predictionBandwidth: 1 MHzFrequency: 14 - 45 MHz
(z ~ 100-30) Multipole: lmax ~ 105 ⇒
CMB observations Planck
z1
2D data
(1) Non-Gaussianity in the primordial fluctuation is crucial to constrain the type of inflation.
(2) The nonlinearity parameter fNL is the key tool to explore the non-Gaussianity. Standard inflation model predicts fNL = O(0.01), while multi-scalar or non-slow-roll inflation scenarios predict fNL > O(0.1).
(3) The 21-cm line tomography works as a promising method to determine fNL. If we achieve DfNL ~ 0.01, we can distinguish inflation models finely and constrain plausible scenarios.
Many realistic problems remain to be solved. Integrated effort from observational and theoretical side is needed!
3. Summary of Part II
Acknowledgement
TTT has been supported by Program for Improvement of Research Environment for Young Researchers from Special Coordination Funds for Promoting Science and Technology commissioned by the Ministry of Education, Culture, Sports, Science and Technology (MEXT) of Japan.