Stellar Death High Mass Stars

1. Stellar DeathHigh Mass Stars

2. Nucleosynthesis Evolutionary Time Scales for a 15 M Star

3. Fe C H He Used energy Released energy Energy Budget Energy Fusion Stages Animation

4. The Final Second • Fe fusion begins • Energy debt results • Core contracts - temperature increases Uncontrollable gravitational collapse • Nuclei converted back into He • He  protons and neutrons • proton + electron  neutron + neutrino • Core Implodes  Envelope Explodes Supernova

5. Anazasi Pictographs

6. The Crab Nebula

7. Supernova 1987a

8. Supernova 1998S inNGC 3877

9. Tycho’s SNR - 1572 Supernova Remnants

10. Core Remnant • Too massive for electron degeneracy to halt collapse (> 1.4 M) • Neutron Degeneracy can halt collapse • M < 3 M • Strong nuclear force • Neutron Star

11. Properties of a Neutron Star • Very small • Gravity balanced by strong nuclear force • R = 10 km • Very Faint • Rapid rotation • Conserve angular momentum • 1000 rotations/s • Intense Magnetic Field • One trillion gauss

12. PSR 0628-28

13. LGM? • Several more found at widely different places in the galaxy • Power of a power equals total power potential output of the Earth • No Doppler shifts PULSARS

14. Light Time Argument • An object which varies its light can be no larger than the distance light can travel in the shortest period of variation.

15. To Darken the Sun Time Delay = Radius/c 500,000 km/300,000 km/s = 1.67 sec

16. Only candidates: White Dwarfs, Neutron Stars

17. Pulse Mechanisms • Binary Stars - How quickly can two stars orbit? • Two WD about 1m • Two NS about 1s. • Neutron Stars in orbit should emit gravity waves which should be detectable. • Oscillations - Depends only on density • WD about ten seconds • NS about .001s Little variation permitted. • Rotation - Until the object begins to break up. • WD about 1s • NS about .001s with large variation.

18. The Crab Pulsar

19. Rotating Neutron Star

20. Lighthouse Model

21. Radiation Magnetic lines of force Electron Synchrotron Radiation

22. Glitches

23. SS 433

24. Relative sizes Neutron Star Earth White Dwarf

25. Mass Limits • Low mass stars • Less than 8 M on Main Sequence • Become White Dwarf (< 1.4 M) • Electron Degeneracy Pressure • High Mass Stars • Less than 40 M on Main Sequence • Become Neutron Stars (3 M < M <1.4 M) • Neutron Degeneracy Pressure

26. Supermassive Stars • If stellar core has more than three solar masses after supernova, then no known force can halt the collapse Black Hole

27. Space-Time No mass Distortion caused by mass

28. Predictions of General Relativity • Advance of Mercury’s perihelion • Bending of starlight

29. Advance of Mercury’s Perihelion Advance in arcsec/cen

30. Apparent position of the star Sun Light from star bent by the gravity of the Sun Bending of Starlight

31. Low Gravity Very small amount of bending

32. Stronger Gravity Light at an angle is bent noticeably

33. Exit Cone and Photon Sphere Photon Sphere

34. Near a Black Hole

35. Event Horizon Rs + Singularity Schwarzschild Black Hole Rs = 3(Mass) Mass Rs 3 M 9 km 5 15 10 30

36. What Can We Know? • Mass • gravity • Charge • Electric Fields • Rotation Rate • Co-rotation

37. How Can We Find Them? • Look for X-ray sources • Must come from compact source • White Dwarf • Neutron Star • Black Hole • Differentiate by Mass • WD - < 1.4 M • NS - between 1.4 and 3 M • BH - > 3 M

39. Cygnus X-1