2. Первичный нуклеосинтез и межзвездные молекулярные H 2 /HD облака на больших красных смещениях Д.Варшалович 1, А.Иванчик 1, П.Петижан 2 2008 Первичный нуклеосинтез и межзвездные молекулярные H 2 /HD облака на больших красных смещениях Д.Варшалович 1, А.Иванчик 1, П.Петижан 2 1 ФТИ им. А.Ф. Иоффе РАН, С.-Петербург, Россия 2 Институт астрофизики Парижа, Франция 2008

4. BBN Epoch: Evolution of Nuclear Composition t ~2.6 min (D/H) max ~ 0.7·10 -2 kT BBN ~ 70 keV n B (BBN) ~ 10 18 -10 19 cm -3 n  (BBN) ~ 10 28 cm -3

5. BBN Yield: Light Nuclei Abundances Standard Model n B ( BBN ) is the only free parameter [D] is the most sensitive to n B (BBN) Under Adiabatic Expansion Contemporary density Fraction of Baryons The Standard Matter Fraction is ~ 5% !!! M H /M B ~0.76 M He4 /M B ~0.24 M Z /M B <10 -4

6. CMBR: T 0 =2.726 K,   (0)=0.26 eV/cm 3, n  (0)=411 cm -3 the Redshifted Thermal Radiation of the Primordial Plasma at the Recombination Epoch: t R ~ 400000 yr, T R ~ 3000 K, n B (R) ~ 300 cm -3, n  (R) ~5·10 11 cm -3 Anisotropy of CMBR CMBR fluctuations  T 0 /T 0 ~10 -5 display a beginning stage of LSS formation. Correlation of the fluctuations Comparison of the theory with observations by WMAP gives: Power spectrum of CMBR fluctuations

8. DI/HI Atomic Lines in QSO Absorption Spectra Ly   1215.67 ÅH I 1215.34 ÅD I  (H I) /  (D I) = 1.00027 [D I] / [H I] (2.0±0.5)   Webb et al. 2000 (2.6±0.4)   Kirkman et al. 2003 Primordial Nucleosynthesis  n B /n      h 2  Const(t)  B  0.044±0.004 (Burles et al. 2001) Difficulties of DI/ HI line identification

14. H 2 absorption lines imprinted in QSO 1232+082 spectrum (z abs = 2.33771)

16. Н 2 rotational level populations N J=5 = (2.3±0.3)  10 14  cm -2 N J=4 = (5.0±0.6)  10 14  cm -2 N J=3 = (2.3±0.5)  10 16  cm -2 N J=2 = (6.0±3.0)  10 16  cm -2 N J=1 = (1.9±0.1)  10 19  cm -2 N J=0 = (2.8±0.1)  10 19  cm -2 N(H 2 ) =  N J = = (4.8±0.2)  10 19  cm -2

17. HD absorption lines imprinted in QSO 1232+082 spectrum (z abs = 2.33771)

19. Interstellar Molecular Clouds 12 Gyr ago: [H 2 ] ~ 4.8·10 19 cm -2 [HD] ~ 3.5·10 15 cm -2 Our Epoch: [H 2 ] ~ 3.4·10 20 cm -2 [HD] ~ 2.1·10 14 cm -2

20. Results n Absorption system z a =2.33771 in Q1232+082 spectrum n The limit of HD/H 2 chemistry n The primordial D abundance 4 He 2 D 3 He 7 Li CMBR

21. D/H abundances vs BBN theory After Big Bang BBN 2.8 min CMBR 3.8  10 5 yr QSO Abs. 8.5  10 8 yr Our Galaxy 1.4  10 10 yr D is destroyed in stars: so D/H decreases during galaxy evolution with cosmological time

22. Conclusions n HD-molecules at high redshift are detected for the first time. n Primeval molecular cloud H 2 -HD existed 12 Gyr ago was discovered. n The ratio of [HD]/[H 2 ] in the primeval cloud is significantly larger than that in the interstellar clouds of our Galaxy. The value n B /n  from [HD]/[H 2 ] agrees with that from 4 He, 3 He, 7 Li observations but disagrees with D/H from DI/HI atomic lines. The value n B /n  from [HD]/[H 2 ] agrees with that from 4 He, 3 He, 7 Li observations but disagrees with D/H from DI/HI atomic lines. The fraction of baryon matter  B from [HD]/[H 2 ] is a bit less but marginally coincides with  B from CMBR WMAP. The fraction of baryon matter  B from [HD]/[H 2 ] is a bit less but marginally coincides with  B from CMBR WMAP.