* Astronomy

Exploding star reconstructed in 3D

Astronomers have put together the first three-dimensional reconstruction of an exploding star (known as a supernova).
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Title: Could the compact remnant of SN 1987A be a quark star?
Authors: T.C. Chan, K.S. Cheng, T. Harko, H.K. Lau, L.M. Lin, W.M. Suen, X.L. Tian

The standard model for Type II supernovae explosion, confirmed by the detection of the neutrinos emitted during the supernova explosion, predicts the formation of a compact object, usually assumed to be a neutron star. However, the lack of the detection of a neutron star or pulsar formed in the SN 1987A still remains an unsolved mystery. In this paper we suggest that the newly formed neutron star at the center of SN1987A may undergo a phase transition after the neutrino trapping time scale (~10 s). Consequently the compact remnant of SN 1987A may be a strange quark star, which has a softer equation of state than that of neutron star matter. Such a phase transition can induce the stellar collapse and result in a large amplitude stellar oscillations. We use a three dimensional Newtonian hydrodynamic code to study the time evolution of the temperature and density at the neutrinosphere. Extremely intense pulsating neutrino fluxes, with submillisecond period and with neutrino energy (> 30 MeV) can be emitted because the oscillations of the temperature and density are out of phase almost 180 degree. If this is true we predict that the current X-ray emission from the compact remnant of SN 1987A will be lower than 10^34 erg s-1, and it should be a thermal bremsstrahlung spectrum for a bare strange star with surface temperature of around ~10^7 K.

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Two decades after it lit up Earths southern skies, the exploding star known as Supernova 1987A is still putting on the fireworks. The first supernova of 1987 had astronomers in a tizzy because it was the brightest one seen since 1604before the invention of the telescope. Instantly they started a global monitoring program, watching for every clue about how massive stars die. Now the Hubble Space Telescope has delivered the pièce de résistance, capturing the supernovas blast wave as it sweeps into interstellar space, heating a surrounding ring of gas into a glowing cosmic rosary.


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Courtesy of NASA/ESA/P.Challis/R.Kirshner
(Harvard Smithsonian Center for Astrophysics)

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February 24, 2007 marks the 20th anniversary of one of the most spectacular events observed by astronomers in modern times, Supernova 1987A. The destruction of a massive star in the Large Magellanic Cloud, a nearby galaxy, spawned detailed observations by many different telescopes, including NASA's Chandra X-ray Observatory and Hubble Space Telescope. The outburst was visible to the naked eye, and is the brightest known supernova in almost 400 years.


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Credit: X-ray: NASA/CXC/PSU/S.Park & D.Burrows.; Optical: NASA/STScI/CfA/P.Challis

Position(J2000): RA 05h 35m 28.30s | Dec -69º 16' 11.10"

This composite image shows the effects of a powerful shock wave moving away from the explosion. Bright spots of X-ray and optical emission arise where the shock collides with structures in the surrounding gas. These structures were carved out by the wind from the destroyed star. Hot-spots in the Hubble image (pink-white) now encircle Supernova 1987A like a necklace of incandescent diamonds. The Chandra data (blue-purple) reveals multimillion-degree gas at the location of the optical hot-spots. These data give valuable insight into the behavior of the doomed star in the years before it exploded.

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