Massive YSOs and the transition to UCHIIs

1. School of Physics & Astronomy FACULTY OF MATHEMATICS & PHYSICAL SCIENCES Massive YSOs and the transition to UCHIIs Melvin Hoare

2. Outline • Definition of MYSOs • Ionized jets and winds • Definition of UCHIIs • Why MYSOs do not ionize their surroundings • RMS Survey population synthesis • Diagnostic Plots • Morphologies • Conclusions

3. Massive Young Stellar Objects • Luminous (>104 L¤) embedded IR point source • bipolar molecular outflow (~10 km s-1) • ionised wind (~100 km s-1) • no UCHII region GL 2591

4. Ionized Jets • MYSOs display weak radio emission • A few have been resolved to show jets • Proper motions show velocities ~500 km s-1 Cep A2 (Patel et al. 2005)

5. Disc winds • Others show evidence of radiation driven disc wind S140 IRS 1 (Hoare 2006) Drew, Proga & Stone (1998)

6. Wind Spectra Gibb & Hoare (2007)

7. IR line wind diagnostics • IR H I recombination lines are formed in the same gas that emits the radio continuum (e.g. Hoeflich & Wehrse 1987) • Ratios of Brackett series lines indicate multiple components: fast optically thick outflow and a narrower optically thinner component S106IR (Lumsden et al. in prep)

8. Spectro-astrometric jet detection W33A Davies et al. (2010)

9. IR line disc diagnostics • Fe II line and CO bandhead formed in dense, neutral material close to star – most likely a disc Lumsden et al. (in prep) Blum et al. (2004)

10. Two views of a disc • CO bandhead also arises in disc • Broader in direct view (edge-on) than in reflected (face-on) view

11. Definition of UCHIIs • In a UCHII the central star is ionizing the surrounding interstellar material and not material driven from the star/disc system MIR dust emission (de Buizer et al. 2002) G29.96-0.02from Megeath et al.

12. Cometary HII Regions • Exponential density gradient, O9V stellar wind and proper motion of 10 kms-1 up density gradient (Arthur & Hoare 2006) Emission measure at i=45o Velocity structure of nebula & wind

13. Why do MYSOs not ionize their surroundings? • Walmsley (1995) suggested that infall quenches the HII region – effectively making it very high EM and therefore not seen in radio • However, likely to still be seen in near-IR recombination lines since • But we do not see very strong, relatively narrow NIR lines • Should also see many bipolar UCHIIs if star has ionizing flux would still escape down the outflow cavity, but we do not.

14. Hosokawa & Omukai (2009) MYSO stars are not hot! • MYSOs do not ionize their surroundings to form a UCHII region as they are swollen by ongoing accretion and therefore have Teff<30 000 K • No MYSOs above L=105 L¤ (M~30 M¤) as they rapidly contract to MS radii and therefore have Teff>30 000 K • Test with population synthesis of the RMS survey of MYSOs and UCHIIs Hosokawa & Omukai (2008)

15. RMS Population Synthesis • Distribute in the spiral arm model (Cordes & Lazio) a n • Sample from a Kroupa IMF • Assume an accretion rate history • Transition to UCHII when on ZAMS and Strömgren expansion thereafter • Include selection criteria F21>MSX completeness limit (~3 Jy), f<20² • Compare to total Galactic star formation rate (~3 M¤yr -1) Davies et al. in prep

16. Accretion Rate History McKee & Tan (2003) Schmeja & Klessen (2004)

17. Evolutionary Tracks Hosokawa priv comm.

18. Increasing Accretion Rate McKee & Tan (2003)

19. Decreasing Accretion Rate Schmeja & Klessen (2004)

20. Evolution

21. Transition Objects • Still predicts that stars above ~ 30 solar masses are accreting whilst in the UCHII phase • Some HII region exciting stars exhibit MYSO spectral features of accretion like the CO bandhead • A few very young bipolar HII regions found such as NGC 7538 IRS 1

22. Diagnostic plots: Size vs linewidth • High frequency lines narrower • No distinction between UCHIIs and HCHIIs G28.20-0.04N (Keto et al. 2008) • HCHII x UCHII o MYSO Hoare et al. (2007) PPV

23. Radio vs IR luminosity • Clear distinction between UCHIIs and MYSOs at luminous end • MYSOs also distinguished from OB star winds – MS OB stars not detected yet Hoare & Franco (2007) ¨ Jets p Evolved OB stars

24. Radio to IR ratio vs speed • Big distinction between UCHIIs and MYSOs • HWZI is a lower limit to wind speed Hoare & Franco (2007)

25. ‘HCHII’ Morphologies - Cometary G24.78+0.08 A1 (Beltran et al. 2007) G34.26+0.15 B (Avalos et al. 2008)

26. ‘HCHII’ Morphologies - Shells G28.20-0.04N (Sewilo et al. 2008) +RRLs G34.26+0.15 B (Avalos et al. 2008)

27. Bipolar – Transition Object? • NGC 7538 IRS 1 is bipolar and variable (Franco-Hernandez & Rodriguez (2004)

28. Outflow not infall • Velocity structure indicates bipolar flow is expanding and not contracting as well as having a decreasing radio flux (Kraus et al. (2006)

29. Conclusions • The vast majority of HCHIIs are just smaller, younger versions of UCHIIs • Not a distinct class of object with different physical process at work • Not to be confused with MYSO winds and jets • However, hyper-compact bipolar HIIs may be important transition objects • e-Merlin, EVLA, MeerKAT high resolution studies may find more of these, but they will be very rare

30. Mm Dust Emission Integrated Peak 24”

31. Modelling H II Region Dust Emission G45.13+0.14A Hoare et al. (1991)

32. Multiple Sources in Beam