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1 Probing the high redshift (2-3) IGM through OVI absorption Sowgat Muzahid (IUCAA, INDIA) Supervisor : R. Srianand (IUCAA, INDIA) Collaborator : P. Petitjean.

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Presentation on theme: "1 Probing the high redshift (2-3) IGM through OVI absorption Sowgat Muzahid (IUCAA, INDIA) Supervisor : R. Srianand (IUCAA, INDIA) Collaborator : P. Petitjean."— Presentation transcript:

1 1 Probing the high redshift (2-3) IGM through OVI absorption Sowgat Muzahid (IUCAA, INDIA) Supervisor : R. Srianand (IUCAA, INDIA) Collaborator : P. Petitjean (IAP, FRANCE)

2 2 Plan of the talk : Introduction Issues we want to address Data Sample and Search procedure Statistical properties of OVI systems Conclusions

3 3 Introduction OVI : fifth ionization state of Oxygen, I. P ~ 113.9 eV Strongest transitions OVI λλ 1032,1037 Å falls in the UV regime Collisional ionization fraction of OVI peaks at T ~ 3 × 10 5 K OVI is the best species to probe : 1. Photo-ionized gas subject to hard ionizing photon. 2. Gas with fairly high temperature where collisional ionization is important. Gnat & Sternberg 2007

4 4 Introduction Census of baryons at low redshift (z< 0.5) implies that ~ 50% of the baryonic mass (as predicted by BBN) is yet to be detected. (Fukugita et al. 1998) Recent numerical simulations predict that a substantial fraction of this “missing baryons” could reside in a warm – hot phase of the IGM. ( [WHIM ], T ~ 10 5 – 10 7 K) (Cen & Ostriker 1999 ; Dave ’ et al. 2001) Relatively cooler phase of the WHIM can be probed by OVI absorption. OVI lines with rest frame EW > 40 mÅ are primarily produced by collisionally ionized gas at : T ~ few 10 5 K and δ ~ 5 – 100. (Fang & Bryan – 2001)

5 5 Issues we are interested in.. Spatial distribution of OVI absorbers hence the high temperature regions and/or regions affected by hard ionizing photons. Physical properties of OVI absorbers at high redshift. Is there any fundamental difference in the properties of what is seen in the local universe ? ( Any Evolution ? ). Estimating the contribution of OVI absorbers to the baryon inventory around redshift 2 - 3. Absorption study is indirect in nature. Big challenge is to relate the LOS properties to the global picture of the absorber. Large homogeneous sample is needed !!

6 6 Data Sample We have ~ 100 high resolution QSO absorption spectra from VLT/UVES. 18 best quality spectra have been picked up to analyze. These data were obtained in the course of the large programme “The Cosmic Evolution of the IGM”. Typical resolution ~ 45,000 (6.6 km/s) and S/R ~ 70 /pixel, wave length coverage 3200 Å to 10,000 Å. This provide a homogeneous sample of QSO sight lines in the redshift range 2.1 - 3.3. These sight lines allow us to study OVI systems for redshift ~ 1.9 - 3.0 where the Ly-alpha forest is not too severe.

7 7 Data Sample We search OVI systems mainly in two ways.. Guided (by other metal lines) search : Blind search : We classify OVI systems mainly into three categories.. Type I : OVI lines are accompanied by other metal lines. Type II : OVI with only Lyman series lines. Type III : OVI with consistent profiles without metal lines and Lyman series lines. This classification is motivated by the facts that.. Type I >> representative of photoionized gas. Type II >> representative of high temp. gas. Type III >> representative of highly ionized and high temp. gas.

8 8 Data Sample Example of a type I (left) and a type II (right) system. We use our own Voigt profile fitting code.

9 9 Data Sample We have identified more than 70 OVI systems ( Biggest OVI sample ever reported ! ). We fit 51 OVI systems comprised of 188 components from 14 LOS. Type I : 45 Type II : 06 Type III : 00 Type II & III systems are always affected by possible Ly-series contaminations which leads to false detections !! Highest redshift : 2.9075 Lowest redshift : 1.9643 Median redshift : 2.32 Median N(HI) : 14.19 cm -2

10 10 Statistical Properties of OVI absorbers No redshift evolution of N(OVI) for 1.9 ≤ z ≤ 2.9.

11 11 Statistical Properties of OVI absorbers With the same spirit of OVI system classification we divide total 188 OVI components into two main categories.. 1. OVI with CIV : 87(188) 2. OVI without CIV : 101(188) This is just to see if there is any difference in properties in this two sub samples which are supposed to trace photoionized and collisionally ionized gas respectively. We will use two indicators for further analysis (a)b-para = 14.4 km/s ( b ≥ 14.4 km/s is consistent with CIE) (b) N OVI = 13.5 cm -2 ( which is the crossover column density according to the simulation of the low redshift OVI systems.)

12 12 Statistical Properties of OVI absorbers 107(188) i.e ~ 57% of total OVI 53(87) i.e ~ 61% of OVI with CIV 54(101) i.e ~ 53% of OVI without CIV components show N(OVI) > 13.5 cm -2 No significant difference between OVI components with and without CIV for N(OVI) > 13.5 cm -2 is seen in a two sided KS test. (only ~ 77% significance level)

13 13 Statistical Properties of OVI absorbers 88(188) i.e ~ 47 % of total OVI 38(87) i.e ~ 44 % OVI with CIV 50(101) i.e ~ 50 % OVI without CIV components show b-parameter consistent with CIE i.e b > 14.4 km/s ( T > 2×10 5 K) A two sided KS test does not show any significant difference between components with and without CIV for b > 14.4 km/s.

14 14 Statistical Properties of OVI absorbers 64(87) ~ 74% components show bOVI > bCIV 22(93) ~ 24% components show bOVI > bHI CIV and OVI are appear to be associated kinematically but originally trace different phases of the (multiphase!) IGM.

15 15 Statistical Properties of OVI absorbers N OVI almost constant for 7 decades variation in N HI. If the HI and OVI phases were well mixed, we would expect multiphase ratio (N HI /N OVI ) to be constant with N HI. Green points are taken from Fox et al. 2007. They have studied hot halos in high redshift protogalaxies. Its intriguing that nowhere (from low density Ly-alpha forests to high density DLAs) OVI is varying that much. N HI /N OVI ~ N HI 1.20± 0.01 Danforth & Shull shown that such correlation exists at low redshift z < 0.15. They found : N HI /N OVI ~ N HI 0.9±0.1 Danforth & Shull-05

16 16 Statistical Properties of OVI absorbers b – N correlation ?? Heckman et al. -02 Radiatively cooling hot gas passing through coronal regime gives rise to such correlation. For log (b) > 1.6, N OVI increases linearly with temp. OVI systems from wide varieties of astrophysical regions (LMC, SMC, HVCs, Halo, Disk, Starburst, IGM) in low redshift show b – N correlation.

17 17 Statistical Properties of OVI absorbers b – N correlation ?? b – N correlation is well known in case of HI (eqn. of state) Here we find mild b-N correlation. r s = 0.5 is good enough to rule out the null hypothesis. Bias ??? Low column with large ‘b’ will be affected by S/N.

18 18 Statistical Properties of OVI absorbers b – N correlation ?? Spearman Rank coefficient: 0.500 Slope = 2.00 ± 0.24 Intercept = 11.20 ± 0.27 Spearman Rank coefficient: 0.537 Slope = 2.02 ± 0.20 Intercept = 11.29 ± 0.23

19 19 Statistical Properties of OVI absorbers A simple model We run CLOUDY v07.02 to model 51 OVI systems. Assumption : a) cloud is optically thin b) cloud is in single phase ! CLOUDY parameters : Stop column density : N(HI) = 15.0 cm -2 HM-05 EGB at redshift 2.32 log Z ~ -3.0 to -1.0 ; log n H ~ -5.0 to -3.5 assuming photoionization !! QSO + GAL QSO

20 20 Conclusions There is no redshift evolution of N OVI between 1.9 < z < 2.9. There is no significant difference in column density distributions between OVI with and without CIV for N OVI > 13.5 cm -2. There is no significant difference in b-parameter distributions between OVI with and without CIV for b > 14.4 km/s. Almost 75% cases we find b OVI > b CIV which indeed imply CIV and OVI probe different phases of the IGM. Increase of multiphase ratio N HI /N OVI with N HI suggests that IGM has at least two phases (WHIM & WNM) and they are not well mixed. Mild log b – log N OVI correlation is there with slope ~ 2.0 which is not due to any bias !! b – N OVI correlation is possibly due to local physics of heating and cooling. A simple model of the OVI systems gives metallicity ~ -3.0 to -1.0 in log and δ ~ 15 – 60 assuming photoionization by Haardt-Madau EGB.

21 21 References Fukugita, M., Hogan, C. J., Peebles, P. J. E., 1998, ApJ, 503, 518 Cen, R., Ostriker, J. P., 1998, ApJ, 514, 1 Dave´, R., et al., 2001, ApJ, 552, 473 Fang, T. & Bryan, G. L., 2001, ApJ, 561, L31 Danforth, C.W. & Shull, M.J., ApJ, 624:560, 2005 Heckman., et al., ApJ, 577:691-700, 2002 Bergeron, J., Aracil, B., Petitjean, P., Pichon, C., A&A 396,L11-15,02 Bergeron, J. & Herbert-Fort., Proceeding IAU Colloquium No 199,2005 Gnat, O. & Strenberg, A., ApJ, 168:213 – 230, 2007 Fox, A. J., et al. A&A 465, 171-184(2007) Haardt, F., & Madau, P. 1996, ApJ, 461, 20 Ferland, G. J., et al., 1998, PASP, 110, 761

22 22 Thank You..

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