The Stellar Graveyard

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The Stellar Graveyard

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ASTR 101 General Astronomy: Stars & Galaxies The Stellar Graveyard NEXT Thursday 10/22: MIDTERM #2 What s In The Stellar Graveyard? Lower mass stars (M< 8Msun)! white dwarfs Gravity vs. electron degeneracy pressure High mass stars (8Msun < M < 30-40 Msun)! neutron stars Gravity vs. neutron degeneracy pressure Even more massive stars (M>30-40 Msun)! black holes Gravity wins When the mass is too great for even neutron degeneracy to hold up when Mcore > 3 Msun Our supernova core collapses to an infinitely small point! Black Hole

Black Holes courtesy of Albert Einstein GENERAL RELATIVITY: (in a nutshell) Einstein s (1911) General Theory of Relativity: gravity is really the warping of spacetime around an object with much mass Masses tell spacetime how to curve. Spacetime, with its curvature, tells masses how to move. Light travels in straight lines and its bending comes from spacetime being curved by gravity [Image from Spacetime and Gravity by S. Carroll] Effects of strong gravity on light can act like lens can redshift light [Image by R. Jantzen]

Gravitational lensing: schematic diagram Gravitational Lensing in the Universe: Two images of a distant quasar A B [Image credit: R. Ellis & I. Smail with HST (NASA/STScI)] Source behind the lens: EINSTEIN RING The arches are the result of gravitational lensing [Image credit: P. Natarajan with HST (NASA/STScI)] [Image credit: L. King with HST (NASA/STScI)]

What is the theory of General Relativity? A. A theory that describes gravity in terms of forces between massive bodies B. A theory that describes gravity in terms of spacetime curvature C. The most general theory of the Universe D. A theory that describes the atom E. A theory that describes how galaxies evolved What is the theory of General Relativity? A. A theory that describes gravity in terms of forces between massive bodies B. A theory that describes gravity in terms of spacetime curvature C. The most general theory of the Universe D. A theory that describes the atom E. A theory that describes how galaxies evolved Black Holes Solutions to the Einstein s equations of General Relativity, describing how spacetime curves around bodies of a certain size and mass. For a given size, the larger the mass, the larger the curvature of spacetime. Black Hole: object whose escape velocity is faster than the speed of light---> can t escape!! Event horizon (Schwarzschild radius) is the point at which escape velocity equals speed of light ~ 3 km for each solar mass in the BH Inside this radius not even light can escape can fall in but never get out We can t see any light coming from inside! BLACK hole NO hard surface!! Event horizon is a theoretical point of no return

Warping of Space by Gravity Light deflection near Black Holes Is EXTREME! An observer can see the back of her head! Gravity imposes curvature on space light s path through space will be bent by gravity within the event horizon, it cannot climb out of the hole As matter approaches event horizon tidal forces are tremendous object would be spaghettified Can we detect BLACK HOLES? [Image by A. Hamilton] Black spot in the sky?

Black Holes in Binaries to the rescue Black Holes in Binaries! X-ray Binary We can detect the effects of black holes on nearby matter (stars, gas, etc.) Astronomers look for compact X-ray binaries Criteria: 1. Invisible star in binary system is too massive to be white dwarf or neutron star Mass > 3 MSun 2.Too small in radius to be a normal star Cygnus X-1: Blue supergiant (strong winds) pours H + He onto accretion disk of black hole Stellar-size black hole Accretion disk Blue supergiant CAN WE IMAGE BLACK HOLES?

Questions on Black Holes? [Simulation credit: P.Armitage] What is a Black Hole? A. A black star B. A concentration of mass with a gravitational field so strong that not even light can escape its grip C. A white dwarf painted in black D. The compact remnant of a low-mass star E. A project that requires large effort with no return What is a Black Hole? A. A black star B. A concentration of mass with a gravitational field so strong that not even light can escape its grip C. A white dwarf painted in black D. The compact remnant of a low-mass star E. A project that requires large effort with no return

GAMMA-RAY BURSTS: witnessing the birth of a new Black Hole in the Universe How it all started.. mid 1960s: VELA satellite looking for signs of nuclear tests TYPICAL GAMMA-RAY BURST Most GRB data gathered by BATSE in the 1990s Main properties of GRBs: Rates: about 1 per day Durations: from tens of milliseconds to several hundreds of seconds, with bimodal distribution Highly variable Short Long

March 2003: a special, very energetic supernova (HYPERNOVA) is found coincident with the position of the (long) GRB Long GRBs are produced by the collapse of a massive star into a Black Hole!! High star rotation likely needed Several pieces of evidence seem to indicate that [Image from http://www.laeff.esa.es/bootes/esp/grb/grb4.htm] Short Gamma-Ray bursts are likely the result of a merger of two compact objects (i.e. NS-NS, NS-BH)

Should we be afraid of GRBs? What is a Gamma-Ray Burst? A powerful GRB in our Galaxy can wipe out life within a distance of several hundred light years. But not very likely to happen A. An energetic burst of gamma rays from the center of the Milky Way. B. An energetic burst of gamma rays from distant galaxies. C. The sign that a new star is born. D. A sign of extraterrestrial life. E. A burst of gamma-rays with duration between 1000 seconds and 1 day What is a Gamma-Ray Burst? A. An energetic burst of gamma rays from the center of the Milky Way. B. An energetic burst of gamma rays from distant galaxies. C. The sign that a new star is born. D. A sign of extraterrestrial life. E. A burst of gamma-rays with duration between 1000 seconds and 1 day What is the likely origin of a longduration Gamma-Ray Burst? A. The merger of two neutron stars. B. The merger of a neutron star and a black hole. C. The collapse of a massive, rapidly rotating star. D. The collapse of a low-mass star. E. The merger of two neutron stars or a neutron star and a black hole.

What is the likely origin of a longduration Gamma-Ray Burst? A. The merger of two neutron stars. B. The merger of a neutron star and a black hole. C. The collapse of a massive, rapidly rotating star. D. The collapse of a low-mass star. E. The merger of two neutron stars or a neutron star and a black hole. What is the likely origin of a shortduration Gamma-Ray Burst? A. The merger of two neutron stars. B. The merger of a neutron star and a black hole. C. The collapse of a massive, rapidly rotating star. D. The collapse of a low-mass star. E. The merger of two neutron stars or a neutron star and a black hole. What is the likely origin of a shortduration Gamma-Ray Burst? A. The merger of two neutron stars. B. The merger of a neutron star and a black hole. C. The collapse of a massive, rapidly rotating star. D. The collapse of a low-mass star. E. The merger of two neutron stars or a neutron star and a black hole.

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