Detection of the Red Supergiant Wind from the Progenitor of Cassiopeia A

Weil, Kathryn E.; Fesen, Robert A.; Patnaude, Daniel; Raymond, J. C.; Chevalier, Roger A.; Milisavljevic, Dan; Gerardy, Christopher L.

doi:10.3847/1538-4357/ab76bf

Cited by 21 publications

(29 citation statements)

References 87 publications

(134 reference statements)

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“…We choose the total RSG lifetime of the secondary as ∆t but this can also be smaller depending on the mass ratio of the binary, so we consider r sh ∼ 100 pc as a conservative upper limit. It is known that there is an Hα cloud located 10-15 pc outside of Cas A in the North East direction (van den Bergh 1971;Weil et al 2020). The location of this cloud is within the ballpark of our inner shell estimate and the one-sided Figure 12.…”

Section: Cassiopeia Asupporting

confidence: 51%

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Formation pathway for lonely stripped-envelope supernova progenitors: implications for Cassiopeia A

Hirai

Sato

Podsiadlowski

et al. 2020

Monthly Notices of the Royal Astronomical Society

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We explore a new scenario for producing stripped-envelope supernova progenitors. In our scenario, the stripped-envelope supernova is the second supernova of the binary, in which the envelope of the secondary was removed during its red supergiant phase by the impact of the first supernova. Through 2D hydrodynamical simulations, we find that ∼50–90 % of the envelope can be unbound as long as the pre-supernova orbital separation is ≲ 5 times the stellar radius. Recombination energy plays a significant role in the unbinding, especially for relatively high mass systems (≳ 18 M⊙). We predict that more than half of the unbound mass should be distributed as a one-sided shell at about ∼10–100 pc away from the second supernova site. We discuss possible applications to known supernova remnants such as Cassiopeia A, RX J1713.7-3946, G11.2-0.3, and find promising agreements. The predicted rate is ∼0.35–1% of the core-collapse population. This new scenario could be a major channel for the subclass of stripped-envelope or type IIL supernovae that lack companion detections like Cassiopeia A.

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Section: Cassiopeia Asupporting

confidence: 51%

“…There are no obvious X-ray features that appear to be the remnant of the primary supernova within 50 pc. The yellow box shows the faint H II region called "Minkowski's H II region" (see van den Bergh 1971;Weil et al 2020).…”

mentioning

confidence: 99%

Formation pathway for lonely stripped-envelope supernova progenitors: implications for Cassiopeia A

Hirai

Sato

Podsiadlowski

et al. 2020

Monthly Notices of the Royal Astronomical Society

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“…The debris of this overrun shell may be associated with the quasi-stationary flocculi in the western part of Cas A (Koo et al 2018). If true, the current reverse shock dynamics may reveal some information about the mass loss history of the Cas A progenitor, which could be combined with the optical information about unshocked CSM as reported by Weil et al (2020) to shed light on the nature of the progenitor star.…”

Section: Why Did the Reverse Shock Reverse Its Direction?mentioning

confidence: 83%

“…The standard scenario for the evolution of Cas A is that of a remnant of a core-collapse SN of Type IIb (Krause et al 2008;Rest et al 2011), with a low ejecta mass of 2-4 M evolving in the clumpy, dense wind of its progenitor (Vink et al 1996;Willingale et al 2003;Chevalier & Oishi 2003;Vink 2004;Hwang & Laming 2012;Weil et al 2020). The observed deviations from spherical symmetry, like the jet and ejecta rings, are usually attributed to asymmetries in the explosion itself, for which light echos from different directions indeed provide evidence (Rest et al 2011).…”

Section: Why Did the Reverse Shock Reverse Its Direction?mentioning

confidence: 99%

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The forward and reverse shock dynamics of Cassiopeia A

Vink,

Patnaude,

Castro

2022

Preprint

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We report on proper motion measurements of the forward-and reverse-shock regions of the supernova remnant Cassiopeia A (Cas A), including deceleration/acceleration measurements of the forward shock. The measurements combine 19 years of observations with the Chandra X-ray Observatory, using the 4.2-6 keV continuum band, preferentially targeting X-ray synchrotron radiation. The average expansion rate is 0.218 ± 0.029%yr −1 for the forward shock, corresponding to a velocity of ≈ 5800 km s −1 . The time derivative of the proper motions indicates deceleration in the east, and an acceleration up to 1.1 × 10 −4 yr −2 in the western part. The reverse shock moves outward in the East, but in the West it moves toward the center with an expansion rate of −0.0225 ± 0.0007 %yr −1 , corresponding to −1884 ± 17 km s −1 . In the West the reverse shock velocity in the ejecta frame is 3000 km s −1 , peaking at ∼ 8000 km s −1 , explaining the presence of X-ray synchrotron emitting filaments there. The backward motion of the reverse shock can be explained by either a scenario in which the forward shock encountered a partial, dense, wind shell, or one in which the shock transgressed initially through a lopsided cavity, created during a brief Wolf-Rayet star phase. Both scenarios are consistent with the local acceleration of the forward shock. Finally we report on the proper motion of the northeastern jet, using both the X-ray continuum band, and the Si XIII K-line emission band. We find expansion rates of respectively 0.21%yr −1 and 0.24%yr −1 , corresponding to velocities at the tip of the X-ray jet of 7830-9200 km s −1 .

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