1	Astro 1050 Mon. Mar 1, 2004 Today: Continue (Finish?) Ch. 9, ISM
2	How does mass affect collapse? More massive protostars have stronger gravity Collapse speed will be much faster Fast collapse and short lifetime means massive stars reach end of lifetime while low mass stars in cloud are just forming Supernova shocks may come from earlier generation of stars Sequential Star Formation Energy from supernova and other effects eventually disrupts cloud – prevents further collapse.
3	Observations of collapse Young cluster “NGC 2264” Few million years old High mass stars have reached main sequence Lower mass stars are still approaching main sequence T Tauri stars Naming of classes of stars: Usually named after first star in class: T Tauri Stars with letters (RR Lyrae) are typically “variable” stars Earlier stages hidden by dust
4	More details of stellar structure and energy generation Alternatives to the proton-proton chain Fusion of Helium to heavier elements Proton-proton reaction slow because: Need two rare events at once High energy collision of 2 protons Conversion of p Þn during collision
5	The CNO Cycle Gives way around need for p ®n during the collision Still must happen later – but don’t need to rare events simultaneously Trade off is need for higher energy collisions (T>16 million K) Add p to some nucleus where new one is still “stable” Wait for p ® n while that nucleus just “sits around” The net effect is still 4 ¹H ® ⁴He C just acts like a “catalyst”
6	Heavy Element Fusion Triple Alpha process ⁴He + ⁴He ® ⁸Be + g ⁸Be + ⁴He ® ¹²C + g Similar type reactions create heavy elements above 600 Million K Plot to left gives: x: # of neutrons y: # of protons Right one – add neutron Up one – add proton Diagonal – p ® n or reverse Jumps: add ⁴He or more
7	Models of Stellar Structure Divide star into thin shells,calculate how following vary from shell to shell (i.e. as function of radius r) P (Pressure) T (Temperature) r (Density) To do this also need to find: M (Mass) contained within any r L (Luminosity) generated within any r P example:
8	Numerical Stellar Models
9	Why don’t stars collapse? Limiting case: Assume no nuclear fusion, only energy source is gravity. Star is “almost” in hydrostatic equilibrium Star radiates energy: If nothing else happened T would drop, P would drop, star would shrink. Star does shrink, but in doing so gravitational energy is converted to heat, preventing T from continuing to drop. In fact, since star is now more compact, gravity is stronger and it actually needs higher P (so higher T) to prevent catastrophic collapse As star shrinks, ½ of gravitational energy goes into heating up star, ½ gets radiated away Rate at which it radiates energy, so rate at which it shrinks, is limited by how “insulating” intermediate layers are
10	Why do we get steady fusion rates? Strange counterintuitive result: As star radiates away thermal energy it actually heats up (because as it shrinks gravity supplies even more energy) Star continues to shrink till it gets hot enough inside for fusion (rather than gravity) to balance energy being radiated away. Nuclear thermostat If fusion reactions took place in a “box” with fixed walls: Fusion Þ more energy Þhigher T Þ more fusion (explosion) If fusion reactions take place in sun with “soft gravity walls”: If fusion rate is too high T tries to go up but star expands and actually ends up cooling off – slowing down fusion. (steady rate)
11	Mass-Luminosity relationship L µ M^3.5Why? Higher mass means higher internal pressure Higher pressure goes with higher temperature Higher temperature means heat leaks out faster Star shrinks until T inside is high enough for fusion rate (which is very sensitive to temperature) to balance heat leak rate
12	Lifetime on Main Sequence L µ M^3.5T µ fuel / L = M/M^{3.5 =} M^-2.5 Example: M=2 M_Sun L = 11.3 L_SunT =1/5.7 T_Sun
13	How about a 0.5 solar mass star? M = 0.5 M_sun Time = Luminosity =
14	How about a 0.5 solar mass star? M = 0.5 M_sun Time = 5.7 times solar lifetime Luminosity = 0.09 solar luminosity
15	Width of Main Sequence – and Stellar Aging As star converts H to He you have more massive nuclei Pressure related to number of nuclei Gravity related to mass of nuclei Pressure would tend to drop unless something else happens Temperature must rise (slightly) to compensate Luminosity must rise (slightly) as heat leaks out faster
16	Orion Nebula: A Star-Forming Region Red light = Hydrogen emission Blue light = reflection nebula Dark lanes = dust Astronomy Picture of the Day: http://antwrp.gsfc.nasa.gov/apod
17	Protoplanetary Disks in the Orion Nebula Dusty disk seen in silhouette Central star visible at long wavelengths
18	Herbig-Haro objects: The angular momentum problem As clouds try to collapse angular momentum makes them spin faster A disk forms around the protostar Material is ejected along the rotation axis
19	Herbig-Haro 34 in Orion Jet along the axis visible as red Lobes at each end where jets run into surrounding gas clouds
20	Motion of Herbig-Haro 34 in Orion Can actually see the knots in the jet move with time In time jets, UV photons, supernova, will disrupt the stellar nursery