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Supernova explosions. Supernova explosions. The lives of stars Type I supernovae Destruction of white dwarfs Type II supernovae Core collapse of massive stars What’s left behind? Pulsars Black Holes. 0. Hertzsprung-Russell diagram. 0. Nova Explosions.
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Supernova explosions • The lives of stars • Type I supernovae • Destruction of white dwarfs • Type II supernovae • Core collapse of massive stars • What’s left behind? • Pulsars • Black Holes
0 Hertzsprung-Russell diagram
0 Nova Explosions Hydrogen accreted through the accretion disk accumulates on the surface of the white dwarf • Very hot, dense layer of non-fusing hydrogen on the white dwarf surface Nova Cygni 1975 • Explosive onset of H fusion • Nova explosion
0 The Chandrasekhar Limit The more massive a white dwarf, the smaller it is. Pressure becomes larger, until electron degeneracy pressure can no longer hold off gravity > Type I supernova WDs with more than ~ 1.4 solar masses can not exist!
0 Time-scales and conditions No need to memorize these numbers. Main thing is to appreciate the differences in the numbers for each evolutionary stage.
Artist’s impression of a supernova Supernova facts ~1/100 yr in our Galaxy ~1/second in Universe Only 0.01% of energy released in visible light! p + e -> n + neutrino Most of energy is in the form of neutrinos!
0 Neutrinos • Elementary particle postulated in 1930 • First detected in 1942 • Miniscule mass and no electric charge • Come in three “flavors” • electron- muon- and tau- • Interact only weakly with other matter
0 Detecting neutrinos Sudbury neutrino detector
Historical Supernovae (Q 2) The youngest supernova explosion occurred in ~1868 and astronomers have just discovered the remnant in the X-ray image shown on the right. The explosion occurred close to the center of our Galaxy and the optical light was obscured from view. www.nasa.gov/mission_pages/chandra/news/08-062.html
0 The Famous Supernova of 1987: Supernova 1987A Before At maximum Unusual type II supernova in the Large Magellanic Cloud in Feb. 1987
How much energy is liberated? • An application of Einstein’s equation • Matter and energy are related as follows E = M c2 • In question 3 we will use this • Take mass of original star • Subtract mass of end product • Subtract mass of expanding shell • Apply the equation to what is left over
Extragalactic Supernovae Why wait? Supernovae are so bright that they can be seen in other Galaxies! Zwicky started such searches and found a total of 120. Currently 984 known. One of their uses is to study the expansion of the Universe (see ASTR 106)
0 Neutron Stars The central core will collapse into a compact object supported by neutron degeneracy pressure. A supernova explosion of an M > 8 Msun star blows away its outer layers. Pressure becomes so high that electrons and protons combine to form stable neutrons throughout the object. Typical size: R ~ 10 km Mass: M ~ 1.4 – 3 Msun Density: r ~ 1014 g/cm3 Piece of neutron star matter of the size of a sugar cube has a mass of ~ 100 million tons!!!
0 Black Holes Just like white dwarfs (Chandrasekhar limit: 1.4 Msun), there is a mass limit for neutron stars: Neutron stars can not exist with masses > 3 Msun We know of no mechanism to halt the collapse of a compact object with > 3 Msun. It will collapse forming a singularity: A BLACK HOLE!
Summary • Supernova are violent stellar explosions • Type I destruction of greedy white dwarfs • Type II core collapse of massive stars • Supernovae produce exotic objects • Neutron stars • Black holes • Supernovae probe the size of the Universe • Type I supernovae act as “standard candles”