Dynamical Instability of White Dwarfs and Breaking of Spherical Symmetry Under the Presence of Extreme Magnetic Fields

Coelho, Jaziel G.; Marinho, R. M.; Malheiro, M.; Negreiros, Rodrigo; Cáceres, D. L.; Rueda, J. A.; Ruffini, Remo

doi:10.1088/0004-637x/794/1/86

Cited by 53 publications

(64 citation statements)

References 49 publications

(69 reference statements)

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“…It was shown by Chandrasekhar & Fermi (1953) that the figure of equilibrium of an incompressible fluid sphere with an internal uniform magnetic field that matches an external dipole field, is not represented by a sphere. The star becomes oblate by contracting along the axis of symmetry, namely along the direction of the magnetic field (see, e.g., Coelho et al 2014). Thus, we consider that the fluid sphere is deformed in such a way that the equation of the ellipticity arising from the magnetic field is given by (Bonazzola & Gourgoulhon 1996;Konno et al 2000;Regimbau & de Freitas Pacheco 2006)…”

Section: Ellipticity Of Magnetized Starsmentioning

confidence: 99%

Gravitational Waves From Pulsars and Their Braking Indices: The Role of a Time Dependent Magnetic Ellipticity

Araújo

Coelho

Costa

2016

ApJ

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We study the role of time dependent magnetic ellipticities ( B ) on the calculation of the braking index of pulsars. Moreover, we study the consequences of such a B on the amplitude of gravitational waves (GWs) generated by pulsars with measured braking indices. We show that, since the ellipticity generated by the magnetic dipole is extremely small, the corresponding amplitude of GWs is much smaller than the amplitude obtained via the spindown limit.

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Section: Ellipticity Of Magnetized Starsmentioning

confidence: 99%

Gravitational Waves From Pulsars and Their Braking Indices: The Role of a Time Dependent Magnetic Ellipticity

Araújo

Coelho

Costa

2016

ApJ

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“…A more detailed study about the Super-Chandrasekhar white dwarfs can be found in Ref. 9 , where we showed that several macro and micro physical aspects such as gravitational, dynamical stability, breaking of spherical symmetry, general relativity, inverse β-decay, and pycnonuclear fusion reactions are of most relevance for the self-consistent description of the structure and assessment of stability of these objects.…”

Section: Results and Conclusionmentioning

confidence: 77%

“…As discussed in Ref. 9 , the hypothetic presence of such large magnetic field would contribute to the gravitational mass of the star leading to m B 25M for the case of the maximum magnetic field considered. Finally, it is important to stress, that the M − R relation of these strongly magnetized white dwarfs obtained in Ref.…”

Section: Introductionmentioning

confidence: 83%

Ultra-magnetized white dwarfs are stable?

Malheiro¹,

Marinho²,

Lobato³

et al. 2017

The Fourteenth Marcel Grossmann Meeting

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Recently the role of huge magnetic fields in white dwarfs (WDs) has been explore. It was proposed the existence of WDs with a magnetic field of 10 18 G with a critical mass Mmax ≈ 2.58M much larger than the Chandrasekhar limit ∼ 1.4M . These Ultra-magnetized super-Chandrasekhar white dwarfs were obtained not considering some physical aspects as virial theorem, breaking of spherical symmetry, inverse β-decay, and pycnonuclear fusion reactions, making them unstable. Taking in account these points, ultra-magnetized, supermassive and stable white dwarfs, with magnetic fields in their interior at maximum of the order of 10 13 − 10 14 G, even difficult to be formed, are possible to exist at least theoretically.

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“…The properties of Fermionic matter have been intensively studied already many decades ago 1 . Recent astrophysical observations have renewed enormous interest in this subject matter [2][3][4] . For instance, it has been suggested that strongly magnetized white dwarfs (SMWDs) with masses greater than the Chandrasekhar mass limit of 1.4 solar masses may be the progenitors of overluminous type-Ia supernovae 2 .…”

Section: Electron Gases In Strong Magnetic Fieldsmentioning

confidence: 99%

Effects of rotation in magnetic white dwarfs

Otoniel¹,

Malheiro²,

Weber³

2017

The Fourteenth Marcel Grossmann Meeting

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The properties of magnetic white dwarfs are computed for an equation of state which describes white dwarf matter in terms of a regular crystal lattice of atomic nuclei at zero temperature, immersed in a totally magnetized electron gas. The minimum critical densities at which electron capture reactions and possibly pycnonuclear fusion reactions occur inside of rotating white dwarfs are studied for different magnetic fields and stellar rotation rates. Moreover we calculate the mass-radius relationships of magnetic white dwarfs for magnetic fields ranging from zero up to 10 13 Gauss and rotational stellar frequencies between zero and the Kepler frequency, which sets an absolute limit on rapid rotation. Our results show that the presence of strong magnetic fields in white dwarfs decreases the value of the critical density for the onset of electron capture and of pycnonuclear reactions. We also find that rotating magnetized white dwarfs may be up to one hundred times less dense than ordinary white dwarfs, depending on their rate of rotation.

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Dynamical Instability of White Dwarfs and Breaking of Spherical Symmetry Under the Presence of Extreme Magnetic Fields

Cited by 53 publications

References 49 publications

Gravitational Waves From Pulsars and Their Braking Indices: The Role of a Time Dependent Magnetic Ellipticity

Gravitational Waves From Pulsars and Their Braking Indices: The Role of a Time Dependent Magnetic Ellipticity

Ultra-magnetized white dwarfs are stable?

Effects of rotation in magnetic white dwarfs

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