Are pulsars born with a hidden magnetic field?

Torres-Forné, A.; Cerdá–Durán, P.; Pons, José A.; Font, José A.

doi:10.1093/mnras/stv2926

Cited by 47 publications

(63 citation statements)

References 79 publications

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“…We focus on both models that collapse to BHs and models where the PNS remains stable throughout the simulation. Although the simulations end too early for observing the crust formation [16] and the late time fall back of magnetized gas [10], we intend to get insights on the field structure of the very young neutron stars. To this end, we focus on the time evolution of the strengths of the poloidal and toroidal components of the surface field and analyze their multipole expansion in spherical harmonics in order to distinguish large-scale structures from the field fluctuating on small scales.…”

Section: Simulationsmentioning

confidence: 99%

“…The time evolution of the rate and geometry of mass accretion and the magnetization of the accreted layers have an important impact on the accumulation of magnetic flux at the PNS surface. The picture thus generated may show a shell of enhanced magnetic field strength, but it is also possible for the magnetic field to be buried underneath additional layers of weakly magnetized gas [10]. These processes are complemented by the possible amplification of magnetic fields in the interior of the PNS, in particular if rotation and convection constitute a dynamo.…”

Section: Introductionmentioning

confidence: 99%

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Evolution of the surface magnetic field of rotating proto-neutron stars

Obergaulinger

Aloy

2017

J. Phys.: Conf. Ser.

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Abstract.We study the evolution of the field on the surface of proto-neutron stars in the immediate aftermath of stellar core collapse by analyzing the results of self-consistent, axisymmetric simulations of the cores of rapidly rotating high-mass stars. To this end, we compare the field topology and the angular spectra of the poloidal and toroidal field components over a time of about one seconds for cores. Both components are characterized by a complex geometry with high power at intermediate angular scales. The structure is mostly the result of the accretion of magnetic flux embedded in the matter falling through the turbulent post-shock layer onto the PNS. Our results may help to guide further studies of the long-term magnetothermal evolution of proto-neutron stars. We find that the accretion of stellar progenitor layers endowed with low or null magnetization bury the magnetic field on the PNS surface very effectively. IntroductionThe wide range of surface magnetic field strengths found across the population of neutron stars (e.g. [1]) is the result of a combination of processes operating at their formation during stellar core collapse and effects that modify their structure afterwards, such as cooling or accretion. Most observations pertain to relatively old neutron stars, and do not place tight constraints on the very early evolution of the field. Hence, it is difficult to draw conclusions on the fields of nascent proto-neutron stars (PNSs) from observations or, conversely, to connect theoretical results from models of supernova core collapse to evolved neutron stars. Nevertheless, the field is likely to bear at least a significant imprint of these early conditions.A thorough theoretical study of the evolution of the magnetic field of PNSs should optimally be based on three-dimensional long-term simulations including magnetohydrodynamics and neutrino transport, which treat the global dynamics of core collapse and a possible supernova explosion and the generation of the PNS field in a self-consistent manner. The enormous computational costs of spectral neutrino transport mean that thus far only a small number of such simulations exist with the most sophisticated ones [2-4] run for only a fairly limited period.Hence, less expensive axisymmetric models are still of considerable use for approaching this topic (e.g. [5][6][7][8][9]). Depending on the rotational energy and the seed field of the pre-collapse star, but also potentially on the input physics and the numerical method and grid resolution, their results range from minor modifications of non-magnetized versions of the same cores to magnetically driven explosions of a preferentially axial morphology. Depending on the global

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Section: Simulationsmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Evolution of the surface magnetic field of rotating proto-neutron stars

Obergaulinger

Aloy

2017

J. Phys.: Conf. Ser.

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“…For example, the recent three-dimensional (3D) numerical simulations for the core-collapse supernova show the existence of the gravitational wave signals associated with the oscillations of PNS (or core region) [15,18,19], whose frequency increases with time from a few hundred Hz up to ∼ kHz in the postbounce phase. This signal is considered either to arise from the fundamental (f -mode) oscillations of the PNS [20,21], the gravity (gmode) like oscillations of the whole region inside the shock radius [22,23], or to be the evidence of the Brunt-Väisälä frequency at the PNS surface (the so-called surface g-mode) [11,13]. Since the Brunt-Väisälä frequency is a local value, which is not associated with the global oscillations of the PNS, the gravitational wave signals in numerical simulations may be a result of the f -mode oscillations of the PNS or the g-mode like oscillations inside the shock radius.…”

Section: Introductionmentioning

confidence: 99%

“…Compared to the extensive studies of asteroseismology for cold neutron stars, the number of the studies of the PNS asteroseismology is relatively limited [20][21][22][23][36][37][38][39][40][41]. This may partially come from the difficulty for preparing the PNS model as a background for the linear analysis.…”

Section: Introductionmentioning

confidence: 99%

“…For the PNS asteroseismology in supernovae, two different approaches have been adopted so far. One approach is the way to construct the PNS model, whose surface is determined by a specific surface density [20,21,39,41], while another approach is that the whole region inside the shock radius is considered as a background [22,23]. For the first approach, one has to select the surface density and the eigenfrequencies of the PNS in the early phase (up to ∼ 500 ms) after core bounce depend on the selection of this density [20,21], but the boundary condition imposed at the surface is simple, i.e., the Lagrangian perturbation should be zero.…”

Section: Introductionmentioning

confidence: 99%

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Determination of properties of protoneutron stars toward black hole formation via gravitational wave observations

Sotani

Sumiyoshi

2019

Phys. Rev. D

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We examine the frequencies of the fundamental (f -) and the gravity (gi-) mode in gravitational waves from accreting protoneutron stars (PNSs) toward black hole formation. For this purpose, we analyze numerical results of gravitational collapse of massive stars for two different progenitors with three equations of state. We adopt profiles of central objects obtained from the numerical simulations by solving general relativistic neutrinoradiation hydrodynamics under the spherical symmetry. Using a series of snapshots as a static configuration at each time step, we solve the eigenvalue problem to determine the specific frequencies of gravitational waves from the evolving PNSs with accretion from core bounce to black hole formation by the relativistic Cowling approximation. We find that the frequency of the f -mode gravitational waves can be expressed as a function of the average density of the PNS at each time step almost independently of the progenitor models in accord with the previous studies on ordinary PNSs. We also find that the ratio of the g1-mode frequency to the f -mode frequency is insensitive to the progenitor, but strongly depends on the compactness of the PNSs. Having a simultaneous observation of the f -and g1-mode gravitational waves, it would provide the information of the average density and compactness of PNS, which can reconstruct the evolution of mass and radius of the PNSs as a constraint on the equation of state at high densities. Furthermore, we show that the highest average density of the PNS with the maximum mass can be estimated with the detection of the f -mode gravitational waves together with the help of the neutrino observations.

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Neutron Stars Formation and Core Collapse Supernovae

Cerdá–Durán

Elias‐Rosa

2018

The Physics and Astrophysics of Neutron Stars

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In the last decade there has been a remarkable increase in our knowledge about core-collapse supernovae (CC-SNe), and the birthplace of neutron stars, from both the observational and the theoretical point of view. Since the 1930's, with the first systematic supernova search, the techniques for discovering and studying extragalactic SNe have improved. Many SNe have been observed, and some of them, have been followed through efficiently and with detail. Furthermore, there has been a significant progress in the theoretical modelling of the scenario, boosted by the arrival of new generations of supercomputers that have allowed to perform multidimensional numerical simulations with unprecedented detail and realism. The joint work of observational and theoretical studies of individual SNe over the whole range of the electromagnetic spectrum has allowed to derive physical parameters, which constrain the nature of the progenitor, and the composition and structure of the star's envelope at the time of the explosion. The observed properties of a CC-SN are an imprint of the physical parameters of the explosion such as mass of the ejecta, kinetic energy of the explosion, the mass loss rate, or the structure of the star before the explosion. In this chapter, we review the current status of SNe observations and theoretical modelling, the connection with their progenitor stars, and the properties of the neutron stars left behind.

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Are pulsars born with a hidden magnetic field?

Cited by 47 publications

References 79 publications

Evolution of the surface magnetic field of rotating proto-neutron stars

Evolution of the surface magnetic field of rotating proto-neutron stars

Determination of properties of protoneutron stars toward black hole formation via gravitational wave observations

Neutron Stars Formation and Core Collapse Supernovae

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