Transcript Document
This set of slides • This set of slides covers the supernova of white dwarf stars and the late-in-life evolution and death of massive stars, stars > 8 solar masses, including supernova of these large mass stars. • Units covered: 65, 66, 67. Mass Transfer and Novae • If a white dwarf is in orbit around a red giant companion star, it can pull material off the companion and into an accretion disk around itself. • Material in the accretion disk eventually spirals inward to the surface of the white dwarf. Novae • If enough material accumulates on the white dwarf’s surface, fusion can be triggered anew at the surface, causing a massive explosion. • This explosion is called a nova (new as in new star.) • If this process happens repeatedly, we have a recurrent nova. The Chandrasekhar Limit and Supernovae • If the mass of one of these accreting white dwarfs exceeds 1.4 solar masses (the Chandrasekhar Limit), gravity wins! (momentarily) • The additional gravity causes just enough compression… • This compression causes the temperature to soar, and this allows carbon and oxygen to begin to fuse into silicon. • The energy released by this fusion blows the star apart in a Type 1a Supernova. Supernova! This is a SINGLE STAR with a luminosity of BILLIONS of stars! Type 1a Supernova – Another Standard Candle • The light output from a Type 1a supernova follows a very predictable curve. – Initial brightness increase followed by a slowly decaying “tail” • All Type 1a supernova have similar peak luminosities, and so can be used to measure the distance to the clusters or galaxies that contain them. Formation of Heavy Elements • Hydrogen and a little helium were formed shortly after the Big Bang. • ALL other elements were formed inside stars. • Low-mass stars create carbon and oxygen in their cores at the end of their life, thanks to the high temperature and pressure present in a red giant star. • High-mass stars produce heavier elements like silicon, magnesium, etc. up through iron, by nuclear fusion in their cores. – Temperatures are much higher. – Pressures are much greater. • Highest-mass elements (heavier than iron) must be created in supernovae - the death of high-mass stars. The Lifespan of a Massive Star Layers of Fusion Reactions • As a massive star burns its hydrogen, helium is left behind, like ashes in a fireplace. • Eventually the temperature climbs enough so that the helium begins to react, fusing into carbon. Hydrogen continues to fuse in a shell around the helium core. • Carbon is left behind until it too starts to fuse into heavier elements. • A nested shell-like structure forms. • Once iron forms in the core, the end is near… Core Collapse of Massive Stars • Iron cannot be fused into any heavier element, so it collects at the center (core) of the star. • Gravity pulls the core of the star to a size smaller than the Earth’s diameter. • The core compresses so much that protons and electrons merge into neutrons, taking energy away from the core. • The core collapses, and the layers above fall rapidly toward the center, where they collide with the core material and “bounce”. • The “bounced material collides with the remaining infalling gas, raising temperatures high enough to set off a massive fusion reaction – an enormous nuclear explosion. • This is a Type II, Ib, or Ic supernova. (Ib, Ic subcatagories) Light Curve for a Supernova The luminosity spikes when the explosion occurs, and then gradually fades, leaving behind a… Supernova Remnant • The supernova has left behind a rapidly expanding shell of heavy elements that were created in the explosion. • Gold, uranium and all other heavy elements all originated in a supernova (Type II) explosion. Types of Supernovae, Summary • Type Ia: The explosion that results from a white dwarf exceeding the Chandrasekhar Limit (1.4 solar masses.) • Type II: Supernovae resulting from massive star core collapse. • Less common: – Type Ib and Ic: Result from core collapse, but lacks hydrogen, lost to stellar winds or other processes. Stellar Corpses • A type II supernova leaves behind the collapsed core of neutrons that started the explosion, a neutron star. • If the neutron star is massive enough, it can collapse, forming a black hole… A Surprise Discovery • Jocelyn Bell, a graduate student working with a group of English astronomers, discovered a periodic signal in the radio part of the spectrum, coming from a distant galaxy. • Astronomers considered (briefly) the possibility of an alien civilization sending the regular pulses. • More pulsating radio sources were discovered These were named pulsars. • All pulsars are extremely periodic, like the ticking of a clock. In some cases, this ticking is amazingly fast! An Explanation • An idea was proposed that eventually solved the mystery. • A neutron star spins very rapidly about its axis, due to conservation of angular momentum. • If the neutron star has a magnetic field, this field can form jets of electromagnetic radiation escaping from the star. • If these jets are pointed at Earth, we can detect them using radio telescopes. • As the neutron star spins, the jets can sweep past earth, creating a signal that looks like a pulse. • Neutron stars can spin very rapidly, so these pulses can be quite close together in time. The Crab Nebula Pulsar Interior Structure of a Neutron Star Density approx. equal to atomic nucleus density. High-Energy Pulsars • Most pulsars emit both visible and radio photons in their beams. • Older neutron stars just emit radio waves. • Some pulsars emit very high energy radiation, such as X-rays. – X-ray pulsars. – Magnetars. • Magnetars have very intense magnetic fields that cause bursts of x-ray and gamma ray photons. 1015 gauss mag field strength. Earth’s field, about 1 gauss.