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Compact Objects Astronomy 315 Professor Lee Carkner Lecture 15
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What are Compact Objects? The densest objects in the universe Can produce strong, high-energy radiation and outbursts when in binary systems
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White Dwarf Mass: Size: earth-sized (~10000 km diameter) Density: Supported by: electron degeneracy pressure Progenitor: Example: nova
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Sirius B In 1844 Bessel determines Sirius is a 50 year binary via astrometry In 1862 Alvan G. Clark finds Sirius B in a telescope test In 1915 Walter Adams uses spectroscopy to get a surface temperature for Sirius B of 27000 K Three times hotter than Sirius A but much fainter than Sirius A
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Observing White Dwarfs White dwarfs are very faint We can only see the near-by ones Hard to find if they aren’t in an interacting binary
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Mass Transfer Stars in a binary can transfer mass have to be close together This material ends up in a accretion disk Friction makes the disk very hot Material will accrete onto the white dwarf
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Cataclysmic Variables Material gets hot as it is compressed by new material White dwarf has strong gravitational field Called a cataclysmic variable We see the star brighten as a nova Cataclysmic variables brighten and fade periodically
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Accretion onto a White Dwarf
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Acceleration of Gravity How much force would you feel if you stood on a white dwarf? Acceleration of gravity (units: m/s 2 ) g = GM/r 2 M is the mass of the star or planet (in kilograms) High mass and small radius means stronger gravity
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Neutron Star Mass: Size: 10 km radius Density: Supported by: neutron degeneracy pressure Progenitor: Example: pulsar
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Above the Limit If a stellar core has mass greater than the Chandrasehkar limit (1.4 M sun ), electron degeneracy pressure cannot support it Supernova breaks apart atomic nuclei Neutrons also obey the Pauli Exclusion principle Cannot occupy the same state
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Neutron Star Properties Small size means low luminosity and high temperature Neutron stars are spinning very rapidly Neutron stars have strong magnetic fields Field is trapped in the collapsing star and is compressed to great strength A trillion times strong than the sun’s
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Pulsars Pulsars are radio sources that blink on and off with very regular periods Each pulse is very short What could produce such short period signals? A large object could not spin fast enough without flying apart Only neutron stars are small enough
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Pulsar in Action The strong magnetic field of a pulsar accelerate charged particles to high velocities The radiation is emitted in a narrow beam outward from the magnetic poles These two beams are swept around like a lighthouse due to the star’s rotation When the beam is pointed at us, the pulsar is “on”, when it is pointed away it is “off”
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A Rotating, Magnetized N.S.
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Viewing Pulsars Pulsars can be associated with supernova remnants The periods of pulsars increase with time We can only see pulsars if the beam is pointing at us Beam is very narrow so some pulsars are undetectable
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Millisecond Pulsars Near the break-up speed Many are found in very old clusters Should have spun down by now
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Pulsars in Binary Systems Mass adds angular momentum to the pulsar and counteracts the natural spin down In extreme cases can produce an powerful magnetically collimated jet Like a T Tauri star
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X-Ray Burster The strong gravitational pressure on this material causes an explosive burst of fusion Produces a burst of X-rays Each burst is about 1000 times as luminous as the sun
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Next Time Read Chapter 22.5-22.8
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