Magnetic field amplification in proto-neutron stars

Naso, L.; Rezzolla, Luciano; Bonanno, A.; Paternò, L.

doi:10.1051/0004-6361:20078360

Cited by 18 publications

(18 citation statements)

References 27 publications

Supporting

Mentioning

Contrasting

Unclassified

Order By: Relevance

“…1. If the effects of turbulence are important, according to Naso et al (2008) diffusivity is much larger and the corresponding Rm is lower (∼10 3 ), but still supercritical. The onset of the shear-Hall instability requires a seed field of the magnitude determined by the actual Rm.…”

Section: Discussionmentioning

confidence: 99%

The shear-Hall instability in newborn neutron stars

Kondić

Rüdiger

Hollerbach

2011

A&A

View full text Add to dashboard Cite

Aims. In the first few minutes of a newborn neutron star's life the Hall effect and differential rotation may both be important. We demonstrate that these two ingredients are sufficient for generating a "shear-Hall instability" and for studying its excitation conditions, growth rates, and characteristic magnetic field patterns. Methods. We numerically solve the induction equation in a spherical shell, with a kinematically prescribed differential rotation profile Ω(s), where s is the cylindrical radius. The Hall term is linearized about an imposed uniform axial field. The linear stability of individual azimuthal modes, both axisymmetric and non-axisymmetric, is then investigated. Results. For the shear-Hall instability to occur, the axial field must be parallel to the rotation axis if Ω(s) decreases outward, whereas if Ω(s) increases outward it must be anti-parallel. The instability draws its energy from the differential rotation, and occurs on the short rotational timescale rather than on the much longer Hall timescale. It operates most efficiently if the Hall time is comparable to the diffusion time. Depending on the precise field strengths B 0 , either axisymmetric or non-axisymmetric modes may be the most unstable. Conclusions. Even if the differential rotation in newborn neutron stars is quenched within minutes, the shear-Hall instability may nevertheless amplify any seed magnetic fields by many orders of magnitude.

show abstract

Section: Discussionmentioning

confidence: 99%

The shear-Hall instability in newborn neutron stars

Kondić

Rüdiger

Hollerbach

2011

A&A

View full text Add to dashboard Cite

show abstract

“…This hypothesis is based on the following qualitative assumptions. Firstly, during the hot proto-NS phase, differential rotation would create strong toroidal MFs inside the NS (Bonanno et al 2003;Naso et al 2008;Frieben & Rezzolla 2012). As a result, realistic models of magnetised NSs require the simultaneous presence of both poloidal and toroidal MF components (Ciolfi & Rezzolla 2013).…”

Section: Introductionmentioning

confidence: 99%

Magnetized hybrid stars: effects of slow and rapid phase transitions at the quark–hadron interface

Mariani

Orsaria

Ranea‐Sandoval

et al. 2019

Monthly Notices of the Royal Astronomical Society

View full text Add to dashboard Cite

We study the influence of strong magnetic fields in hybrid stars, composed by hadrons and a pure quark matter core, and analyse their structure and stability as well as some possible evolution channels due to the magnetic field decay. Using an ad-hoc parametrisation of the magnetic field strength and taking into account Landau-quantization effects in matter, we calculate hybrid magnetised equations of state and some associated quantities, such as particle abundances and matter magnetisation, for different sets of parameters and different magnetic field strengths. Moreover, we compute the magnetised stable stellar configurations, the mass versus radius and the gravitational mass versus central energy density relationships, the gravitational mass versus baryon mass diagram, and the tidal deformability. Our results are in agreement with both, the ∼ 2M pulsars and the data obtained from GW170817. In addition, we study the stability of stellar configurations assuming that slow and rapid phase transitions occur at the sharp hadron-quark interface. We find that, unlike in the rapid transition scenario, where ∂ M/∂ c < 0 is a sufficient condition for instability, in the slow transition scenario there exists a connected extended stable branch beyond the maximum mass star, for which ∂ M/∂ c < 0. Finally, analysing the gravitational mass versus baryon mass relationship, we have calculated the energy released in transitions between stable stellar configurations. We find that the inclusion of the magnetic field and the existence of new stable branches allows the possibility of new channels of transitions that fulfil the energy requirements to explain Gamma Ray Bursts. From a model-theoretical point of view, magnetars are magnetised NSs (M ∼ 2 M , R ∼ 15 km (Glendenning 1997)) with an external solid crust and an internal extremely dense

show abstract

“…In addition to rapid rotation, also strong magnetic fields can introduce significant deformations in neutron stars, as shown, for instance, by Bocquet, Gourgoulhon & Novak () and Cardall, Prakash & Lattimer (), who have computed fully non‐linear models of relativistic stars with a poloidal magnetic field. At the end of the collapse of the core of a massive star, differential rotation could create strong toroidal magnetic fields of the order of

10^{16} -- 10^{17} G

inside the hot protoneutron star (Bonanno, Rezzolla & Urpin ; Naso et al ; Bonazzola & Haensel, unpublished). As a result, realistic models of magnetized relativistic stars require the simultaneous presence of both poloidal and toroidal field components.…”

Section: Introductionmentioning

confidence: 99%

Equilibrium models of relativistic stars with a toroidal magnetic field

Frieben

Rezzolla

2012

Monthly Notices of the Royal Astronomical Society

Self Cite

157

177

View full text Add to dashboard Cite

We have computed models of rotating relativistic stars with a toroidal magnetic field and investigated the combined effects of magnetic field and rotation on the apparent shape (i.e. the surface deformation), which could be relevant for the electromagnetic emission, and on the internal matter distribution (i.e. the quadrupole distortion), which could be relevant for the emission of gravitational waves. Using a sample of eight different cold nuclear-physics equations of state, we have computed models of maximum field strength, as well as the distortion coefficients for the surface and the quadrupolar deformations. Surprisingly, we find that non-rotating models admit arbitrary levels of magnetisation, accompanied by a growth of size and quadrupole distortion to which we could not find a limit. Rotating models, on the other hand, are subject to a mass-shedding limit at frequencies well below the corresponding ones for unmagnetised stars. Overall, the space of solutions can be split into three distinct classes for which the surface deformation and the quadrupole distortion are either: prolate and prolate, oblate and prolate, or oblate and oblate, respectively. We also derive a simple formula expressing the relativistic distortion coefficients and that allows one to compute the surface deformation and the quadrupole distortion up to significant levels of rotation and magnetisation, essentially covering all known magnetars. Such formula replaces Newtonian equivalent expressions that overestimate the quadrupole distortion by about a factor of five and are inadequate for strongly-relativistic objects like neutron stars

show abstract

Magnetic field amplification in proto-neutron stars

Cited by 18 publications

References 27 publications

The shear-Hall instability in newborn neutron stars

The shear-Hall instability in newborn neutron stars

Magnetized hybrid stars: effects of slow and rapid phase transitions at the quark–hadron interface

Equilibrium models of relativistic stars with a toroidal magnetic field

Contact Info

Product

Resources

About