Hints of a second explosion (a quark nova) in Cassiopeia A supernova

Ouyed, Rachid; Leahy, D. A.; Koning, Nico

doi:10.1088/1674-4527/15/4/003

Cited by 9 publications

(6 citation statements)

References 76 publications

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“…The environments around these objects are expected to be complex, and some models explain magnetar-like behaviour through accretion from fall-back material on to the surface of the object (Ouyed, Leahy & Niebergal 2007). Interest in the quark nova scenario has grown considerably due in part to the NuSTAR observations of the Cassiopeia A supernova remnant (Grefenstette et al 2014) which detected a discrepancy in the distribution of titanium-44 and iron-56 abundances that can be explained by the quark nova scenario (Ouyed, Leahy & Koning 2015). Considerations of more realistic dispersion relations coupled with GR may be relevant in the dynamic environment around an energetic, highly compact quark star.…”

Section: Discussionmentioning

confidence: 99%

Frequency-dependent effects of gravitational lensing within plasma

Rogers

2015

Monthly Notices of the Royal Astronomical Society

124

120

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The interaction between refraction from a distribution of inhomogeneous plasma and gravitational lensing introduces novel effects to the paths of light rays passing by a massive object. The plasma contributes additional terms to the equations of motion, and the resulting ray trajectories are frequency-dependent. Lensing phenomena and circular orbits are investigated for plasma density distributions N ∝ 1/r h with h ≥ 0 in the Schwarzschild space-time. For rays passing by the mass near the plasma frequency refractive effects can dominate, effectively turning the gravitational lens into a mirror. We obtain the turning points, circular orbit radii, and angular momentum for general h. Previous results have shown that light rays behave like massive particles with an effective mass given by the plasma frequency for a constant density h = 0. We study the behaviour for general h and show that when h = 2 the plasma term acts like an additional contribution to the angular momentum of the passing ray. When h = 3 the potential and radii of circular orbits are analogous to those found in studies of massless scalar fields on the Schwarzschild background. As a physically motivated example we study the pulse profiles of a compact object with antipodal hotspots sheathed in a dense plasma, which shows dramatic frequency-dependent shifts from the behaviour in vacuum. Finally, we consider the potential observability and applications of such frequency-dependent plasma effects in general relativity for several types of neutron star.

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Section: Discussionmentioning

confidence: 99%

Frequency-dependent effects of gravitational lensing within plasma

Rogers

2015

Monthly Notices of the Royal Astronomical Society

124

120

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“…As a consequence, observations of Cassiopeia A put stringent constraints on the critical temperatures of the neutron superfluid and proton super-conductor in neutron-star cores [207,208,209]. However, this interpretation has been questioned and alternative scenarios have been proposed [210,211,212,213,214,215,216,217] (most of which still requiring superfluidity and/or superconductivity in neutron stars).…”

Section: Rapid Cooling Of Cassiopeia Amentioning

confidence: 99%

Superfluidity and Superconductivity in Neutron Stars

Chamel

2017

J Astrophys Astron

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Neutron stars, the compact stellar remnants of core-collapse supernova explosions, are unique cosmic laboratories for exploring novel phases of matter under extreme conditions. In particular, the occurrence of superfluidity and superconductivity in neutron stars will be briefly reviewed.Comment: Has appeared in Journal of Astrophysics and Astronomy special issue on "Physics of Neutron Stars and Related Objects", celebrating the 75th birth-year of G. Srinivasa

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“…We account for the luminosity 12 , the photometric/spectroscopic signatures 13 as well as introduce nuclear/spallation signatures resulting from the interaction of the ultra-relativistic QN ejecta with the SN shell and circumstellar material 14 . For shorter time-delays of less than a day, the QN kinetic energy is lost to PdV work but the collision between the r-process-rich QN ejecta with the SN ejecta yields unique nuclear signatures which may explain existing observations 15 . The QS shows features reminiscent of soft gamma repeaters 16,17 while the explosion energetics and variability are reminiscent of gamma-ray bursts 18 .…”

Section: Quark Nova : Overview Energetics and Dynamicsmentioning

confidence: 97%

“…14 For shorter time-delays of less than a day, the QN kinetic energy is lost to PdV work but the collision between the r-process-rich QN ejecta with the SN ejecta yields unique nuclear signatures which may explain existing observations. 15 The QS shows features reminiscent of soft gamma repeaters 16,17 while the explosion energetics and variability are reminiscent of gamma-ray bursts.…”

Section: Quark Nova : Overview Energetics and Dynamicsmentioning

confidence: 99%

Quark-novae in binaries: Observational signatures and implications to astrophysics

Ouyed¹,

Leahy²,

Koning³

et al. 2017

The Fourteenth Marcel Grossmann Meeting

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The explosive transition of a massive neutron star to a quark star (the Quark-Nova; QN) releases in excess of ∼ 10 52 erg in kinetic energy which can drastically impact the surrounding environment of the QN. A QN is triggered when a neutron star gains enough mass to reach the critical value for quark deconfinement to happen in the core. In binaries, a neutron star has access to mass reservoirs (e.g. accretion from a companion or from a Common Envelope; CE). We explain observed light-curves of hydrogen-poor superluminous Supernovae (SLSNe Ia) in the context of a QN occurring in the second CE phase of a massive binary. In particular this model gives good fits to light-curves of SLSNe with double-humped light-curves. Our model suggests the QN as a mechanism for CE ejection and that they be taken into account during binary evolution. In a short period binary with a white dwarf companion, the neutron star can quickly grow in mass and experience a QN event. Part of the QN ejecta collides with the white dwarf; shocking, compressing; and heating it to driving a thermonuclear runaway producing a SN Ia impostor (a QN-Ia). Unlike "normal" Type Ia supernovae where no compact remnant is formed, a QN-Ia produces a quark star undergoing rapid spin-down providing additional power along with the 56 Ni decay energy. Type Ia SNe are used as standard candles and contamination of this data by QNe-Ia can infer an incorrect cosmology.

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Hints of a second explosion (a quark nova) in Cassiopeia A supernova

Cited by 9 publications

References 76 publications

Frequency-dependent effects of gravitational lensing within plasma

Frequency-dependent effects of gravitational lensing within plasma

Superfluidity and Superconductivity in Neutron Stars

Quark-novae in binaries: Observational signatures and implications to astrophysics

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