梅村 雅之 筑波大学 物理学系 （計算物理学研究センター）

1. 銀河形成 梅村　雅之 筑波大学　物理学系　（計算物理学研究センター） I. 銀河形成の初期条件／境界条件 II. 第一世代天体 IIＩ. 宇宙再電離 IV. 銀河形成と進化

2. 赤方 偏移 天体の起源 物質の起源 時間 量子ゆらぎ 量子宇宙 10-44秒 1030 古典ゆらぎ （ハリソン－ゼルドビッチスペクトル） ダークマター生成 陽子・中性子（バリオン）形成 密度ゆらぎ （宇宙背景放射ゆらぎ） 軽元素合成 （p,n,He,D,T,Be,Li） 103 50万年 宇宙再結合 Dark Age 重元素合成 超新星爆発 α元素, r-,s-過程元素, ... 第一世代天体 1億年 15 宇宙再電離 銀河形成 SNII α元素, r-,s-過程元素, ... （クェーサー，星，BH） SNIa 鉄族元素, ... 5 銀河団 太陽系 140億年 ０ 有機物 宇宙大規模構造 生命 （現在）

3. I. 銀河形成の初期条件と境界条件 1. Cosmological Parameters 2. Fluctuation Spectrum 3. Reionization

4. COBE =7°– 180° WMAP =0.2°– 180°

5. WMAP 理論

6. Cosmological Parameters (CDM Universe) Fluctuation Spectrum (CDM)

7. Thomson optical depth (Reionization)

8. First Objects (Pop III) CMB n=1 gg Mgal Mcluster CDM Density Fluctuations Neutral Ionized 30 1 10 Dwarf Galaxies 1+zc Galaxies Clusters 1

9. II. 第一世代天体 1. H2 Formation 2. First Objects 3. First Stars

10. 初期ゆらぎの重力収縮 ジーンズ条件（重力エネルギー＞熱エネルギー） 密度上昇　← 冷却過程で支配される  現在の銀河 重元素冷却，ダスト冷却  第一世代天体 星が生まれていない　⇒　重元素がない 重元素以外の冷却　⇒　水素分子

11.  e- p + - e- p  水素分子形成 電気双極子モーメント=0　⇒　H+H→H2+ 禁止 H ３体反応 （高密度） H2 e.g. 宇宙晴れ上がり時 （低密度） 陽子反応 (z100) 電子反応 (z100) H2 H2 H H H- H+

12. Formation of Pop III Stars Reaction 1: e-+ H  H- + h  H- + H  H2 + e- (z100) Reaction 2: p + H  H2 ++ hH2 ++ H  H2+ p (z100) Matsuda, Sato, & Takeda (1969, Prog. Theor. Phys., 42, 219) Non-equilibrium processes equilibrium non-equilibrium Susa et al. (1998, PTP, 100, 63) IGM (residual ion. e10-5): H210-5 No shock ion. (Ts<104K): H2 10-4 – 10-3 Shock ion. (Ts >104K): H210-3 –10-2

13. First Object Mass Yoshida et al. (2003, ApJ, 592, 645) 60million particles 100M per gas particle Mhalo  106 M

14. Pop III Stars Gravitational Energy＝Internal Energy 3D (sphere)M = const. 1D (sheet)M/r2 = const. 2D (cylinder)M/r = const. Nishi et al. (1998, PTP, 100, 881)

15. Fragmentation of Cylinder Rate equation e-, H, H+, H-, H2, H2+, D, D+, HD, He, He+, He++ Level population (regarding level j ) Ckj Akj j Ajk Cjk Bjk Radiation transfer (or Escape probability ) Cooling function

16. Critical Density ncrit Ckj Akj j Ajk Cjk Ckj Ckj j Cjk Cjk

17. Fragment Mass at ncrit H2 cooling A20 ~ 2.94  10-11

18. Opacity Limited Mass Uehara et al. (1996, ApJ, 473, L95) Rees (1976, MNRAS, 176, 483) (Chandrasekhar mass) Nakamura & Umemura (2001, ApJ, 548, 19) 2D Simulation

19. =0.1 Nakamura & Umemura (2001, ApJ, 548, 19) Initial high density leads to low fragment mass.

20. （M） Pop III Star IMF Fragment mass criterion + CDM spectrum Nakamura & Umemura (2001, ApJ, 548, 19)

21. HD Molecule Cooling UV ionization(e.g. Corbelli et al. 1998; Susa & Umemura 2000) Shock ionization(e.g. Shapiro & Kang 1987; Ferrara 1998) High H2 abundance HD: A10 ~ 5.12  10-8 c.f. H2: A20 ~ 2.94  10-11 HD Cooling critical density:

22. Opacity Limited Mass HD cooling Uehara & Inutsuka 2000, ApJ, 531, L91 Nakamura & Umemura (2002, ApJ, 569, 549)

23. Pop III Pop I Mcore10-3 M 10-3 M Mfrag 103M>0.1M M10-3 M/yr10-5 M/yr . Protostellar Collapse Omukai & Nishi 1998, ApJ, 508, 141; Omukai 2000, ApJ, 534, 809 2nd core Z/Z 1st core grain temperature Conversion of Kelvin-Helmholtz Contraction

24. Envelope: 103 M Core:10-2 M Infall Rate: 10-2 M/yr

25. SN Explosion of Massive Stars Umeda & Nomoto 2002, ApJ, 565, 385

26. End-Product of Massive Stars Heger et al. 2003, ApJ, 591, 288 Type I Collapsar: BH formation by core collapse Type II Collapsar: BH formation by fallback caused by SN shock Type III Collapsar: BH formation without proto-neutron star formation JetSN: Hypernova GRB: long GR burst（a portion of Jet SNs） Z/Z 1 Pair 0

27. III. 宇宙再電離 1. Self-Shielding 2. Reionization History 3. UVB History

28. Propagation of Ionizing Front Yoshida et al. 2003 Stars in molecular gas clouds HII regions + soft UV

29. Early Reionization Process Ciardi, Ferrara & White 2003, MNRAS, 334, L17 z = 17.6 z=15.5 z=13.7 Larson IMF (Top-heavy) Salpeter IMF

30. Self-Shielding Tajiri & MU (1998, ApJ, 502, 59) UV background: I0=I21 10-21(ν/νL)- erg s-1 cm-2 Hz-1 str-1 =1-5 Radiation transfer Ionization equilibrium

31. Spherical Top-Hat Cloud Numerical Results (n>ncrit ; HI>0.1) Strömgren approximation Number of incident UV Number of recombination photons per second to excited states per second = Strömgren approximation underestimates the self-shielding.

32. Reionization History in Inhomogeneous Universe Nakamoto, MU, Susa (2001, MNRAS, 321, 593) 3次元輻射輸送方程式 自由度: 3D space, 2D directions, 1D frequency = 6D Space: N3＝1283 in (8Mpc)3 Directions:NθNφ＝128 2 Frequency:Nν＝6 lines for H & He, analytic integration for continuum • Total operations:f NiterN3NθNφNν＝11.4 Tflops・hr ( f 2000, Niter=100) • Performed with the CP-PACS (614GFLOPS)

33. Zel’dovich approx. withΩCDM=0.95, ΩBaryon=0.05, σ8=0.6, h=0.5 Isotropic UV: I0=I21 10-21(ν/νL)-1 erg s-1 cm-2 Hz-1 str-1 N3＝1283 in (8Mpc) 3 Radiative Transfer Ionization Equilibrium

34. QSO

35. Nakamoto, MU, Susa (2001, MNRAS, 321, 593) I21=0.1 3億年 5億年 7億年 10億年

36. Self-Shielding （自己遮蔽） Shadowing （日陰効果） Z=9 Z=7 Z=5

37. Cosmic Reionization History and Effect of Inhomogeniety

38. Thomson Optical Depth (Poster: Hiroi, MU, Nakamoto) 0.2 0.1 I21 > 0.1 at z >14 optical depth τe(z) 0.04 ：I21=0.1 ：I21=10-2 0.02 ：optically thin 10-2 4 8 12 16 20 z

39. Redshift z<4 z≈4 4<z<6 z>14 z≈20 Method proximity effect DA DA te te I21 0.5±0.1 Giallongo et al. 1996 I21≈1 I21≈0.1 I21 > 0.1 I21 ≥ 1 free Evolution of UVB Intensity I21 1 WMAP 0.5 proximity effect Ly  continuum depression 0.1 4 6 14 20 Redshift

40. IV. 銀河形成と進化 1. Formation of Subgalactic Objects 2. Formation of Normal Galaxies 3. Galactic Evolution

41. First Objects (Pop III) CMB n=1 gg Mgal Mcluster CDM Density Fluctuations Neutral Ionized 30 1 10 Dwarf Galaxies 1+zc Galaxies Clusters 1

42. ...Werner band Solomon Process Lyman-Werner band : 11.26-13.6 eV 15% of excited states decay to the continuuum (v>15)  photodissociation (Solomon process) 85% populate vib-rotational levels of v14  fluorescence lines

43. Rate coefficient of Solomon process Self-shielding(Draine & Bertordi 1996, ApJ, 468, 269)

44. Radiation Hydrodynamical Collapse of Subgalactic Clouds under UVB Kitayama, Susa, MU, Ikeuchi 2001, MNRAS, 326, 1353 UV: Radiative transfer including self-shielding for LW band Spectral shape : power-law, Planck Dynamics: Spherical Lagrangian Hydrodynamics H2 : Non-equilubrium chemistry including H- photo-detachment H2+ photo-dissociation

45. self-shielding UV Effects Kitayama et al. 2001, MNRAS, 326, 1353 Dynamics: Spherical hydrodynamics UV: Radiative transfer H2 : Non-equilubrium chemistry

46. Substructure Problem Moore et al. 1999, ApJ, 524, L19 Cluster Halo Moore et al. 1999 Galactic Halo 20 times smaller than expected

47. 再電離宇宙における矮小銀河形成 （Susa & MU 2004, ApJ, in press）

49. dissipationless GF dissipational GF Elliptical Galaxies Spiral Galaxies 銀河形態の起源 • Merger Hypothesis Disk major merger  Ellipticals N-body, Hydro-simulation, Semi-analytic • Monolithic Bifurcation (Larson’s paradigm) Protogalactic clouds

50. GC3 - Grand Challenge Cosmology Consortium- Cluster Simulations on the PSC Cray T3E John Dubinski