Imprints of the jittering jets explosion mechanism in the morphology of the supernova remnant SNR 0540-69.3

Soker, Noam

doi:10.48550/arxiv.2109.10230

Cited by 2 publications

(3 citation statements)

References 44 publications

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“…In the delayed neutrino mechanism neutrinos heat the post-shock collapsing matter and revive the stalled shock (e.g., Bethe & Wilson 1985;Couch & Ott 2013;Bruenn et al 2016;Janka et al 2016;Müller et al 2019;Burrows & Vartanyan 2021;Fujibayashi et al 2021;Boccioli et al 2022;Nakamura, Takiwaki, & Kotake 2022). In the jittering jets explosion mechanism the newly born NS (or black hole; BH) launches jets that deliver the energy to the ejecta (e.g., Soker 2010;Papish & Soker 2011;Gilkis & Soker 2014;Papish & Soker 2014;Quataert et al 2019;Shishkin & Soker 2021;Antoni & Quataert 2022;Shishkin & Soker 2022;Soker 2022).…”

Section: Introductionmentioning

confidence: 99%

Post-explosion positive jet-feedback activity in inner ejecta of core collapse supernovae

Akashi,

Soker

2022

Preprint

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We conduct three-dimensional hydrodynamical simulations of weak jets that we launch into a core collapse supernovae (CCSNe) ejecta half an hour after the explosion and find that the interaction of the fast jets with the CCSN ejecta creates high pressure zones that induce a backflow that results in mass accretion onto the newly born neutron star. In cases of weak jets, a total power of ≈ 10 45 −10 46 erg, the backflow mass accretion might power up to an order of magnitude more energetic jets. In total, the jets of the two post-explosion jet-launching episodes have enough energy to influence the morphology of the very inner ejecta, a mass of ≈ 0.1M . Our results imply that in some, probably a minority of, CCSN remnants the very inner regions might display a bipolar structure that results from post-explosion weak jets. The regions outside this part might display the morphology of jittering jets.

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Section: Introductionmentioning

confidence: 99%

Post-explosion positive jet-feedback activity in inner ejecta of core collapse supernovae

Akashi,

Soker

2022

Preprint

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“…A possible case for the present setting is one where there are N launch = 4, or few more, jet-launching episodes as I claimed for the supernova remnant SNR 0540-69.3 (Soker 2022), each lasting τ j 0.03 s or somewhat less. The total energy of the four jetlaunching episode is 1.2 × 10 51 erg, which after adding the contribution from neutrino heating that I study here and removing the binding energy of the ejecta gives a typical CCSN explosion energy.…”

Section: The Jetsmentioning

confidence: 95%

“…According to the delayed neutrino mechanism (Bethe & Wilson 1985) neutrinos heat the material in the post-shock zone behind the stalled shock, the gain region, and after some delay the heating revives the stalled shock in a non-spherical manner (e.g., Couch & Ott 2013;Bruenn et al 2016;Janka et al 2016;O'Connor & Couch 2018;Müller et al 2019;Burrows & Vartanyan 2021;Fujibayashi et al 2021;Boccioli et al 2022). According to the jittering jets explosion mechanism (Soker 2010) the proto-NS, or later the newly born NS or a black hole (BH) if it is formed, launches jets that deposit sufficient amounts of energy to the collapsing core material outside the stalled shock and by that explode the star (e.g., Papish & Soker 2011, 2014bGilkis & Soker 2015;Quataert et al 2019;Soker 2020;Antoni & Quataert 2022;Shishkin & Soker 2022;Soker 2022).…”

Section: Introductionmentioning

confidence: 99%

Boosting jittering jets by neutrino heating in core collapse supernovae

Soker

2022

Preprint

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I estimate the energy that neutrino heating add to the outflow that jets induce in the collapsing core material in core collapse supernovae (CCSNe), and find that this energy crudely doubles the energy that the jets deposit into the core. I consider the jittering jets explosion mechanism where there are several stochastic jet-launching episodes, each lasting for about 0.01-0.1 seconds. The collapsing core material pass through the stalled shock at about 100 km and then slowly flows onto the protoneutron star (NS). I assume that the proto-NS launches jittering jets, and that the jets break out from the stalled shock. I examine the boosting process by which the high-pressure gas inside the stalled shock, the gain region material, expands alongside the jets and does work on the material that the jets shock, the cocoon. This work is crudely equal to the energy that the original jets carry. I argue that the coupling between instabilities, stochastic rotation, magnetic fields, and jittering jets lead to most CCSN explosions. In other cases, the pre-collapse core is rapidly rotating and therefore ordered rotation replaces stochastic rotation and fix jets replace jittering jets.

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Imprints of the jittering jets explosion mechanism in the morphology of the supernova remnant SNR 0540-69.3

Cited by 2 publications

References 44 publications

Post-explosion positive jet-feedback activity in inner ejecta of core collapse supernovae

Post-explosion positive jet-feedback activity in inner ejecta of core collapse supernovae

Boosting jittering jets by neutrino heating in core collapse supernovae

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