Lecture 14

1. Lecture 14 Star formation

2. Insterstellar dust and gas • Dust and gas is mostly found in galaxy disks, and blocks optical light

3. The interstellar medium • Stars are born from this gas and dust, collectively known as the interstellar medium. • During their lifetime, stars may return some material to the ISM through surface winds or explosive events

4. Composition of the ISM • Hydrogen is by far the most common element in the ISM • Molecular (H2) • Neutral (HI) • Ionized (HII) • Also contains helium and other elements. The solid component is in the form of dust.

5. Neutral hydrogen • HI can emit radiation if the electron flips its spin angular momentum vector. • This is a very small energy difference of only 5.9 meV, corresponding to a wavelength l=21 cm. • - corresponds to radio frequencies, 1420 MHz

6. The Milky Way in optical light • A map of neutral H in the Milky Way

7. Neutral Hydrogen in the Milky Way • HI gas in the Milky Way clearly reveals spiral structure

8. Properties of interstellar dust • Grain sizes: 1nm-10 mm (i.e. similar to visible light) • Composition: graphite, SiC, silicates, H2, H2O

9. Interstellar dust • Interstellar dust is likely produced in the envelopes around red supergiant stars. • Radiate in the infrared (cooling mechanism) • Are easily destroyed by collisions

10. Interstellar extinction • Dust scatters starlight. Thus a star behind a dust cloud will appear fainter. The apparent magnitude of a star is therefore: • where d is measured in parsecs, and al is the number of magnitudes of extinction along the line of sight. How is this related to the optical depth?

11. Molecular clouds • When hydrogen becomes dense enough, molecules of H2 form: • H2 is nearly impossible to observe: there are no emission or absorption lines at visible or radio wavlengths • Thus we rely on tracer molecules, most commonly CO but also CH, OH, CS and C3H2.

12. Types of molecular clouds • Giant molecular clouds • T~20 K • n~1x108-3x108 m-3 • M~106 MSun • R~50 pc • Translucent clouds • T=15-50 K • n~5x108-5x109 m-3 • M~3-100 MSun • R~ 1-10 pc • aV~1-5 • Giant molecular cloud cores • T~100-200 K • n~1x1013-3x1015 m-3 • M~10 – 1000 MSun • R<1 pc • aV~50-1000

13. The sites of star formation • The cores of molecular clouds are likely sites of new star formation

14. The formation of protostars • There are many unanswered questions about the formation of protostars • Since they form in very dense, opaque clouds of dust and gas they are very difficult to observe in detail

15. Break

16. The Jeans mass • A simple energetic argument can give a rough approximation for the conditions required for a molecular cloud to collapse and form stars. • The virial theorem relates (time-averaged) kinetic to potential energy, for a stable, gravitationally bound system: • This indicates a stability criterion: if the kinetic energy is too low, the cloud will collapse under the force of gravity • This defines a critical mass, known as the Jeans mass: • It can also be expressed as a radius, in terms of the Jeans length: • The two are related by:

17. Example: molecular cloud cores • What is the Jeans mass for a molecular cloud core? • Thus these cores should be collapsing under the weight of their own gravity, consistent with their association with the sites of star formation.

18. Cloud collapse • A collapsing molecular cloud starts off simply: • In free-fall, assuming the pressure gradients are too small to have much effect • The gas is approximately isothermal, if gas is optically thin so energy can be efficiently radiated away. • The time it takes for the shell containing mass Mr to collapse to r=0 is the free-fall time scale:

19. Example: cloud collapse • Notice the collapse starts off slowly, but the density increases sharply during the final stages.