* Astronomy

NASA'S Chandra Finds Superfluid in Neutron Star's Core

This new research has allowed the teams to place the first observational constraints on a range of properties of superfluid material in neutron stars. The critical temperature was constrained to between one half a billion to just under a billion degrees Celsius. A wide region of the neutron star is expected to be forming a neutron superfluid as observed now, and to fully explain the rapid cooling, the protons in the neutron star must have formed a superfluid even earlier after the explosion. Because they are charged particles, the protons also form a superconductor.
Using a model that has been constrained by the Chandra observations, the future behaviour of the neutron star has been predicted. The rapid cooling is expected to continue for a few decades and then it should slow down.
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Title: Rapid Cooling of the Neutron Star in Cassiopeia A Triggered by Neutron Superfluidity in Dense Matter
Authors: Dany Page (1), Madappa Prakash (2), James M. Lattimer (3), Andrew W. Steiner (4) ((1) Instituto de Astronomia, Universidad Nacional Autonoma de Mexico, (2) Department of Physics and Astrononmy, Ohio University (3) Department of Physics and Astronomy, State University of New York at Stony Brook (4) Joint Institute for Nuclear Astrophysics, National Superconducting Cyclotron Laboratory and Department of Physics and Astrononmy, Michigan State University)
(Version v2)

We propose that the observed cooling of the neutron star in Cassiopeia A is due to enhanced neutrino emission from the recent onset of the breaking and formation of neutron Cooper pairs in the 3P2 channel. We find that the critical temperature for this superfluid transition is ~0.5x10^9 K. The observed rapidity of the cooling implies that protons were already in a superconducting state with a larger critical temperature. Our prediction that this cooling will continue for several decades at the present rate can be tested by continuous monitoring of this neutron star.

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Title: The Three-Dimensional Structure of Interior Ejecta in Cassiopeia A at High Spectral Resolution
Authors: Karl Isensee, Lawrence Rudnick, Tracey DeLaney, J.D. Smith, Jeonghee Rho, William T. Reach, Takashi Kozasa, Haley Gomez

We used the Spitzer Space Telescope's Infrared Spectrograph to create a high resolution spectral map of the central region of the Cassiopeia A supernova remnant, allowing us to make a Doppler reconstruction of its 3D structure. The ejecta responsible for this emission have not yet encountered the remnant's reverse shock or the circumstellar medium, making it an ideal laboratory for exploring the dynamics of the supernova explosion itself. We observe that the O, Si, and S ejecta can form both sheet-like structures as well as filaments. Si and O, which come from different nucleosynthetic layers of the star, are observed to be coincident in velocity space in some regions, and separated by 500 km/s or more in others. Ejecta travelling toward us are, on average, ~900 km/s slower than the material travelling away from us. We compare our observations to recent supernova explosion models and find that no single model can simultaneously reproduce all the observed features. However, models of different supernova explosions can collectively produce the observed geometries and structures of the interior emission. We use the results from the models to address the conditions during the supernova explosion, concentrating on asymmetries in the shock structure. We also predict that the back surface of Cassiopeia A will begin brightening in ~30 years, and the front surface in ~100 years.

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