1. Doubly Dead Stars
A binary system eventually ends as two compact objects
Usually nothing else happens
If very close (neutron stars or black holes) more happens
Stars emit gravitational waves – they move closer
Merge to make black hole
Some gamma ray bursters occur this way
Three ways to make a black hole
Very massive star death (> 30 MSun)
Accretion onto neutron star
Merger of two neutron stars

2. Gravitational Waves
When two neutron stars, two black holes, or one of each merge, they should cause fluctuations in space–time
Gravitational waves
February 11, 2016: LIGO announces discovery of gravitational waves
Produced by merging black holes
29 MSun merged with 37 Msun
1.3 billion light years away
August 17, 2017: LIGO announces detection of gravitational waves from neutron star merger
Combined with gamma ray burst
Followed by supernova observation

3. Cosmic Recycling
It is believed that the hydrogen and helium in stars was created at the beginning of time, the “big bang”
What about the other elements?
Red Giants and Double Shell-burning stars lose gas from their outer layers
Add carbon, oxygen and nitrogen to the universe
Supernovae contribute all other elements
Both Massive Star Supernovae and White Dwarf Supernovae
We now think neutron star mergers also produce some of the heaviest elements
Such as gold
Later generations of stellar systems contain all elements
Like our stellar system!

4. End of Material for Test 3
L = 4d2B
Test 3 Review Online
4 H + 2e -  He + 2 neutrino + energy
Questions?

5. Levels of Organization
The Milky Way
Levels of Organization
From smallest to biggest:
Stellar systems (binaries, etc.)
Stellar Clusters
Galaxies
Galaxy Groups and Clusters
Galaxy Superclusters
The Universe
Our Galaxy is called the Milky Way

6. The Milky Way: Visible Light
Center of Galaxy
Obscured by gas and dust
Galactic Plane

7. The Milky Way
The central portion
Baade’s Window

8. The Milky Way – From Outside

9. The Milky Way – From Outside

10. Q. 87: Pictures of Milky Way from the Outside
The Milky Way – Edge On
Q. 87: Pictures of Milky Way from the Outside

11. The Milky Way – Artist’s Conception
Our galaxy is hard to study because we are inside it
We are in the galactic plane, filled with obscuring dust
Other galaxies are hard to study because they are far away
Generalize from far away to nearby and vice versa
You are here

12. The Milky Way – Basic Structure
Galaxies and larger structures are incredibly large compared to anything we have studied up to now
We need new units to describe it
The Sun
The disk
The bulge
The nucleus
The halo
Globular clusters
Distances
ly = 0.931016 m
kly = 103 ly
Mly = 106 ly
Gly = 109 ly

13. The Disk – Dimensions and Structure
The bulge
The nucleus
The halo
Globular clusters
A large, flat disk, shaped like a pancake
About 100 kly in diameter
About 3 kly thick
We are about half way out
Has prominent spiral structure
27 kly
The Sun
3 kly
100 kly

14. The Disk - Composition Stars, mixture of young and old
Circular orbits in plane of galaxy
From 0 to about 10 Gyr
Open clusters
The interstellar medium
Hot bubbles
Atomic hydrogen clouds
Molecular clouds
Ionization nebulae
Dust
Obscures and reddens things
Causes “reflection nebulae”
The disk
The bulge
The nucleus
The halo
Globular clusters

15. Open Clusters
NGC 290
M35
NGC 2158
Pleiades M6
M36

16. Hot Bubbles The disk Gas heated by supernovae and other violent events
The bulge
The nucleus
The halo
Globular clusters
Gas heated by supernovae and other violent events
Gas is very thin
Gas is very hot and ionized
Temperatures up to 106 K
Can be traced out by X-rays

17. Hot Bubbles - Images

18. Atomic Hydrogen Clouds
Slightly cooler regions of gas
Hydrogen atoms produce 21 cm line
Electron and proton are spinning and have magnetic interactions
When electron spin flips over, 21 cm radio emission is seen
21 cm line used to map out our disk
Can also get accurate Doppler shift
The disk
The bulge
The nucleus
The halo
Globular clusters
Radio waves
Q. 88: Doppler Shift From 21 cm Line

19. The 21 cm line

20. Approximate Map of Galaxy

21. Molecular Clouds Coldest and densest regions
Atoms join together to make molecules
Principally hydrogen (H2), but this is difficult to detect
Other molecules vibrate to produce characteristic radio waves
These regions are where new stars can form
Carbon monoxide (CO) emissions from cool clouds in our galaxy

22. Molecular Clouds – Eagle Nebula

23. Molecular Clouds

24. Molecular Clouds – Keyhole and Orion

25. Molecular Clouds

26. Molecular Clouds – Horsehead Nebula

27. Ionization (Emission) Nebulae
The disk
The bulge
The nucleus
The halo
Globular clusters
Light from hot stars ionizes hydrogen
Hot thin gas
When it recombines, light is made
Q. 89: Spectrum from an Emission Nebula
Light

28. Ionization (Emission) Nebulae

29. Ionization (Emission) Nebulae

30. Labeled Eagle Nebula