Electron-positron energy deposition rate from neutrino pair annihilation in the equatorial plane of rapidly rotating neutron and quark stars

Abstract: The neutrino–antineutrino annihilation into electron–positron pairs near the surface of compact general relativistic stars could play an important role in supernova explosions, neutron star collapse, or for close neutron star binaries near their last stable orbit. General relativistic effects increase the energy deposition rates due to the annihilation process. We investigate the deposition of energy and momentum due to the annihilations of neutrinos and antineutrinos in the equatorial plane of the rapidly rot… Show more

“…Similar plots can be found in Birkl et al (2007), where the EMDR distribution near the black holes was determined for different kinds of neutrino tori and disc models under the assumption of non‐isotropic neutrino–antineutrino scattering. Our results are also consistent with the previous works presenting the EMDR calculations along the rotational axis and the equatorial plane of the same neutron and quark star models (Kovács et al 2010, 2011).…”

“…The latter is defined to be the radius where the pressure of the stellar matter drops to zero in the equatorial plane. Since the configurations of the stellar models considered here do not produce stars compact enough to form a neutrino‐sphere trapping the (anti)neutrinos, the entire surface of the accretion disc is considered as a neutrino–antineutrino source (Kovács et al 2010).…”

“…In Figs 3 and 4 we present the EMDR derived at 10 4 observers in the zx plane above the accretion disc for the rotating neutron and quark star models with the same total mass M and angular frequency Ω, when the neutrino temperature of the disc is set to the constant T (3 r g ). As in Kovács et al (2010, 2011), we consider the configurations for M = 1.8 M ⊙ and Ω= 5000 s −1 for each EOS. The physical parameters for these stellar models are presented in Table A1 ().…”

“…For black holes the area of the effective source of the radiation is proportional to the spin parameter, and a rapidly rotating black hole can enhance the energy–momentum deposition in its vicinity from neutrino–antineutrino annihilation (Asano & Fukuyama 2001; Miller et al 2003). In Kovács et al (2010, 2011) it was shown that this relation between the EDMR and a * will break down in the case of some stellar models, where the surface of the strongly deformed star in the equatorial plane not only prevents the radiant area of the disc from the further increase, but also reduces this area by forcing the inner edge of the disc to locate at higher and higher radii. Although the higher spin indeed enhances the deposition rate even for the rapidly rotating stars with DH, BBBParis, BBBAV14 and APR type EOSs, the stiff RMF and the STOS0 models, together with the quark stars, do not follow this relation.…”

“…In most of the previous investigations of the neutrino annihilation processes the central compact object was assumed to be a black hole. A comparative study of the neutrino annihilation process from neutrinos emitted by accretions discs around neutron and quark stars was initiated in Kovács, Cheng & Harko (2010), and further developed in Kovács, Cheng & Harko (2011). In these studies the electron–positron energy deposition rate was obtained in the equatorial plane and along the rotation axis of neutron and quark stars, described by several equations of state.…”

General relativistic ray-tracing algorithm for the determination of the electron-positron energy deposition rate from neutrino pair annihilation around rotating neutron and quark stars

“…Similar plots can be found in Birkl et al (2007), where the EMDR distribution near the black holes was determined for different kinds of neutrino tori and disc models under the assumption of non‐isotropic neutrino–antineutrino scattering. Our results are also consistent with the previous works presenting the EMDR calculations along the rotational axis and the equatorial plane of the same neutron and quark star models (Kovács et al 2010, 2011).…”

“…The latter is defined to be the radius where the pressure of the stellar matter drops to zero in the equatorial plane. Since the configurations of the stellar models considered here do not produce stars compact enough to form a neutrino‐sphere trapping the (anti)neutrinos, the entire surface of the accretion disc is considered as a neutrino–antineutrino source (Kovács et al 2010).…”

“…In Figs 3 and 4 we present the EMDR derived at 10 4 observers in the zx plane above the accretion disc for the rotating neutron and quark star models with the same total mass M and angular frequency Ω, when the neutrino temperature of the disc is set to the constant T (3 r g ). As in Kovács et al (2010, 2011), we consider the configurations for M = 1.8 M ⊙ and Ω= 5000 s −1 for each EOS. The physical parameters for these stellar models are presented in Table A1 ().…”

“…For black holes the area of the effective source of the radiation is proportional to the spin parameter, and a rapidly rotating black hole can enhance the energy–momentum deposition in its vicinity from neutrino–antineutrino annihilation (Asano & Fukuyama 2001; Miller et al 2003). In Kovács et al (2010, 2011) it was shown that this relation between the EDMR and a * will break down in the case of some stellar models, where the surface of the strongly deformed star in the equatorial plane not only prevents the radiant area of the disc from the further increase, but also reduces this area by forcing the inner edge of the disc to locate at higher and higher radii. Although the higher spin indeed enhances the deposition rate even for the rapidly rotating stars with DH, BBBParis, BBBAV14 and APR type EOSs, the stiff RMF and the STOS0 models, together with the quark stars, do not follow this relation.…”

“…In most of the previous investigations of the neutrino annihilation processes the central compact object was assumed to be a black hole. A comparative study of the neutrino annihilation process from neutrinos emitted by accretions discs around neutron and quark stars was initiated in Kovács, Cheng & Harko (2010), and further developed in Kovács, Cheng & Harko (2011). In these studies the electron–positron energy deposition rate was obtained in the equatorial plane and along the rotation axis of neutron and quark stars, described by several equations of state.…”

General relativistic ray-tracing algorithm for the determination of the electron-positron energy deposition rate from neutrino pair annihilation around rotating neutron and quark stars

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