Death of Stars II Neutron StarsSlide Number 2Guiding QuestionsScientists first proposed the existence of neutron stars in the 1930sThe discovery of pulsars in the 1960s stimulated interest in neutron starsPulsars are rapidly rotating neutron stars with intense magnetic fieldsSlide Number 7Slide Number 8Slide Number 9Slide Number 10Superfluidity and superconductivity are among the strange properties of neutron starsSlide Number 12Slide Number 13Pulsars gradually slow down as they radiate energy into spaceSlide Number 15The fastest pulsars were probably created by mass transfer in close binary systemsSlide Number 17Slide Number 18Pulsating X-ray sources are also neutron stars in close binary systemsSlide Number 20Slide Number 21Explosive thermonuclear processes on white dwarfs and neutron stars produce novae and burstersSlide Number 23Slide Number 24Slide Number 25Like a white dwarf, a neutron star has an upper limit on its massJargon1Death of Stars II Neutron Stars2REMEMBER THIS !?3Guiding Questions1. What led scientists to the idea of a neutron star?2. What are pulsars, and how were they discovered?3. How did astronomers determine the connection between pulsars and neutron stars?4. How can a neutron star supply energy to a surrounding nebula?5. What are conditions like inside a neutron star?6. How are some neutron stars able to spin several hundred times per second?7. Why do some pulsars emit fantastic amounts of X rays?8. Are X-ray bursters and novae similar to supernovae?9. How massive can a neutron star be?4Scientists first proposed the existence of neutron stars in the 1930s• A neutron star is a dense stellar corpse consisting primarily of closely packed degenerate neutrons• A neutron star typically has a diameter of about 20 km, a mass less than 3 times the mass of the Sun, a magnetic field 1012 times stronger than that of the Sun, and a rotation period of roughly 1 second • Zwicky and Baade proposed that a highly compact ball of neutrons would produce a degenerate neutron pressure in star remnants too large to become white dwarfs– Not verified until 1960’s5The discovery of pulsars in the 1960s stimulated interest in neutron stars6Pulsars are rapidly rotating neutron stars with intense magnetic fields• A pulsar is a source of periodic pulses of radio radiation• These pulses are produced as beams of radio waves from a neutron star’s magnetic poles sweep past the Earth7• Intense beams of radiation emanate from regions near the north and south magnetic poles of a neutron star• These beams are produced by streams of charged particles moving in the star’s intense magnetic field891011Superfluidity and superconductivity are among the strange properties of neutron stars• A neutron star consists of a superfluid, superconducting core surrounded by a superfluid mantle and a thin, brittle crust• There is evidence for an “atmosphere”121314Pulsars gradually slow down as they radiate energy into space• The pulse rate of many pulsars is slowing down steadily• This reflects the gradual slowing of the neutron star’s rotation as it radiates energy into space• Sudden speedups of the pulse rate, called glitches, may be caused by interactions between the neutron star’s crust and its superfluid interior or material falling onto the crust1516The fastest pulsars were probably created by mass transfer in close binary systems• If a neutron star is in a close binary system with an ordinary star, tidal forces will draw gas from the ordinary star onto the neutron star• The transfer of material onto the neutron star can make it rotate extremely rapidly, giving rise to a millisecond pulsar171819Pulsating X-ray sources are also neutron stars in close binary systems• Magnetic forces can funnel the gas onto the neutron star’s magnetic poles, producing hot spots• These hot spots then radiate intense beams of X rays• As the neutron star rotates, the X-ray beams appear to flash on and off• Such a system is called a pulsating X-ray variable202122Explosive thermonuclear processes on white dwarfs and neutron stars produce novae and bursters• Material from an ordinary star in a close binary can fall onto the surface of the companion white dwarf or neutron star to produce a surface layer in which thermonuclear reactions can explosively ignite• Explosive hydrogen fusion may occur in the surface layer of a companion white dwarf, producing the sudden increase in luminosity that we call a nova• The peak luminosity of a nova is only 10–4 of that observed in a supernova• Explosive helium fusion may occur in the surface layer of a companion neutron star• This produces a sudden increase in X-ray radiation, which we call a burster23242526Like a white dwarf, a neutron star has an upper limit on its mass• The pressure within a neutron star comes from two sources– One is the degenerate nature of the neutrons, and the other is the strong nuclear force that acts between the neutrons themselves• The discovery of neutron stars inspired astrophysicists to examine seriously one of the most bizarre objects ever predicted by modern science, the black hole27Jargon• degenerate neutron pressure• glitch• millisecond pulsar• neutron star• nova (plural novae)• pair production• pulsar• pulsating X-ray source• superconductivity• superfluidity• synchrotron radiation• X-ray