C. G. Bernal scite author profile

We present magnetohydrodynamic numerical simulations of the late post-supernova hypercritical accretion to understand its effect on the magnetic field of the new-born neutron star. We consider as an example the case of a magnetic field loop protruding from the star's surface. The accreting matter is assumed to be non magnetized and, due to the high accretion rate, matter pressure dominates over magnetic pressure. We find that an accretion envelope develops very rapidly and once it becomes convectively stable the magnetic field is easily buried and pushed into the newly forming neutron star crust. However, for low enough accretion rates the accretion envelope remains convective for an extended period of time and only partial submergence of the magnetic field occurs due to a residual field that is maintained at the interface between the forming crust and the convective envelope. In this latter case, the outcome should be a weakly magnetized neutron star with a likely complicated field geometry. In our simulations we find the transition from total to partial submergence to occur aroundṀ ∼ 10M yr −1 . Back-diffusion of the submerged magnetic field toward the surface, and the resulting growth of the dipolar component, may result in a delayed switch-on of a pulsar on time-scales of centuries to millenia.

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Signatures of neutrino cooling in the SN1987A scenario

Fraija¹,

Bernal²,

Hidalgo-Gámez³

2014

Monthly Notices of the Royal Astronomical Society

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The neutrino signal from SN1987A confirmed the core-collapse scenario and the possible formation of a neutron star. Although this compact object has eluded all observations, theoretical and numerical developments have allowed a glimpse of the fate of it. In particular, a hypercritical accretion model has been proposed to forecast the accretion of ∼ 0.15 M in two hours and the subsequent submergence of the magnetic field in the newborn neutron star. In this paper, we revisit the Chevalier's model in a numerical framework, focusing on the neutrino cooling effect on the supernova fall-back dynamics. For that, using a customized version of the FLASH code, we carry out numerical simulations of the accretion of matter onto the newborn neutron star in order to estimate the size of the neutrino-sphere, the emissivity and luminosity of neutrinos. As a signature of this phase, we estimate the neutrinos expected on SK neutrino experiment and their flavor ratios. This is academically important because, although currently it was very difficult to detect 1.46 thermal neutrinos and their oscillations, these fingerprints are the only viable and reliable way to confirm the hypercritical phase. Perhaps new techniques for detecting neutrino oscillations arise in the near future allowing us to confirm our estimates.

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The Gravitational Drag Force on an Extended Object Moving in a Gas

Bernal¹,

Sánchez-Salcedo

2013

ApJ

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Using axisymmetrical numerical simulations, we revisit the gravitational drag felt by a gravitational Plummer sphere with mass M and core radius R s , moving at constant velocity V 0 through a background homogeneous medium of adiabatic gas. Since the potential is non-diverging, there is no gas removal due to accretion. When R s is larger than the Bondi radius R B , the perturbation is linear at every point and the drag force is well fitted by the time-dependent Ostriker's formula with r min = 2.25R s , where r min is the minimum impact parameter in the Coulomb logarithm. In the deep nonlinear supersonic regime (R s ≪ R B ), the minimum radius is no longer related with R s but with R B . We find r min = 3.3M −2.5 R B , for Mach numbers of the perturber between 1.5 and 4, although r min = 2M −2 R B = 2GM/V 2 0 also provides a good fit at M > 2. As a consequence, the drag force does not depend sensitively on the nonlinearity parameter A, defined as R B /R s , for A-values larger than a certain critical value A cr . We show that our generalized Ostriker's formula for the drag force is more accurate than the formula suggested by Kim & Kim (2009).

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Many Aspects of Magnetic Fields in Neutron Stars

et al. 2018

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Abstract:In this work, we explore different aspects in which strong magnetic fields play a role in the composition, structure and evolution of neutron stars. More specifically, we discuss (i) how strong magnetic fields change the equation of state of dense matter, alter its composition, and create anisotropies, (ii) how they change the structure of neutron stars (such mass and radius) and the formalism necessary to calculate those changes, and (iii) how they can affect neutron stars' evolution. In particular, we focus on how a time-dependent magnetic field modifies the cooling of a special group known as X-ray dim neutron stars.

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Hypercritical accretion scenario in central compact objects accompanied with an expected neutrino burst

et al. 2018

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The measurement of the period and period derivative, and the canonical model of dipole radiation have provided a method to estimate the low superficial magnetic fields in the so-called Central Compact Objects (CCOs). In the present work, a scenario is introduced in order to explain the magnetic behavior of such CCOs. Based on magnetohydrodynamic simulations of the post core-collapse supernova phase during the hypercritical accretion episode, we argue that the magnetic field of a newborn neutron star could have been early buried. During this phase, thermal neutrinos are created mainly by the pair annihilation, plasmon decay, photo-neutrino emission and other processes. We study the dynamics of these neutrinos in this environment and also estimate the number expected of the neutrino events with their flavor ratios on Earth. The neutrino burst is the only viable observable that could provide compelling evidence of the hypercritical phase and therefore, the hidden magnetic field mechanism as the most favorable scenario to explain the anomalous low magnetic fields estimated for CCOs.

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C. G. Bernal

Hypercritical Accretion Onto a Newborn Neutron Star and Magnetic Field Submergence

Signatures of neutrino cooling in the SN1987A scenario

The Gravitational Drag Force on an Extended Object Moving in a Gas

Many Aspects of Magnetic Fields in Neutron Stars

Hypercritical accretion scenario in central compact objects accompanied with an expected neutrino burst

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