Type II superconductivity and magnetic flux transport in neutron stars

Jones, P. B.

doi:10.1111/j.1365-2966.2005.09724.x

Cited by 37 publications

(66 citation statements)

References 24 publications

Supporting

Mentioning

Contrasting

Order By: Relevance

“…If present at all, type I superconductivity with an admixture of field free superconducting regions and magnetic normal matter domains exists near the centre of the star (Jones 2006). When the core protons underwent transition into type II superconductivity, Meissner currents in the crust-core interface played a boundary condition for the coupled evolution of the magnetic field within the normal matter crust and superconducting core which is unknown currently (Jones 2004).…”

Section: The Model: Vortex Creep Across Toroidal Flux Tubesmentioning

confidence: 99%

“…Long term magnetic field evolution determines the presence and extent of the toroidal field region within the neutron star core. Following the formation of the neutron star the mixed magnetic field configuration with poloidal and toroidal components are inherited from progenitor star (Braithwaite 2009) and after the transition into superconducting state this field form is frozen into the neutron star plasma due to the enhanced electrical conductivity (Jones 2006). Flux tubes move out as a result of diffusion processes, forces acting on them and secular interaction with vortex lines.…”

mentioning

confidence: 99%

See 1 more Smart Citation

Post-glitch exponential relaxation of radio pulsars and magnetars in terms of vortex creep across flux tubes

Gügercinoğlu¹

2017

Monthly Notices of the Royal Astronomical Society

View full text Add to dashboard Cite

Timing observations of rapidly rotating neutron stars revealed a great number of glitches, observed both from canonical radio pulsars and magnetars. Among them, 76 glitches have shown exponential relaxation(s) with characteristic decay times ranging from several days to a few months, followed by a more gradual recovery. Glitches displaying exponential relaxation with single or multiple decay time constants are analysed in terms of a model based on the interaction of the vortex lines with the toroidal arrangement of flux tubes in the outer core of the neutron star. Model results agree with the observed timescales in general. Thus, the glitch phenomenon can be used to deduce valuable information about neutron star structure, in particular on the interior magnetic field configuration which is unaccessible from surface observations. One immediate conclusion is that the magnetar glitch data are best explained with a much cooler core and therefore require that direct Urca type fast cooling mechanisms should be effective for magnetars.

show abstract

Section: The Model: Vortex Creep Across Toroidal Flux Tubesmentioning

confidence: 99%

mentioning

confidence: 99%

Post-glitch exponential relaxation of radio pulsars and magnetars in terms of vortex creep across flux tubes

Gügercinoğlu¹

2017

Monthly Notices of the Royal Astronomical Society

View full text Add to dashboard Cite

show abstract

“…In the low‐temperature limit, ω 0 τ≫ 1, only a small longitudinal component of the spectral flow force, given by , remains. Owing to the cancellation of the Magnus force, reduces to f B + f V + F sf ∥ = 0, showing that the movement of proton vortices, and hence expulsion of the field, occurs easily under the influence of buoyancy forces or of interaction with outward‐moving neutron vortices as the rotation of the star slows (Jones 2006). At higher temperatures, the existence of spectral flow radically changes this behaviour.…”

Section: Application To Proton Vorticesmentioning

confidence: 99%

“…The distinct populations of superfluid quasi‐particles concerned are those localized in the cores of proton vortices and those delocalized in the continuum. Previous vortex velocity calculations (Jones 2006) assumed both the internal temperatures T < 10 8 K of typical radio pulsars and negligibly small neutron and proton quasi‐particle number densities. Under these conditions, proton vortices and therefore the internal flux distribution could be quickly expelled to the core‐crust boundary.…”

Section: Introductionmentioning

confidence: 99%

Fermion zero-mode influence on neutron-star magnetic field evolution

Jones¹

2009

Monthly Notices of the Royal Astronomical Society

Self Cite

View full text Add to dashboard Cite

The quantum phenomenon of spectral flow which has been observed in laboratory superfluids, such as 3He-B, controls the drift velocity of proton type II superconductor vortices in the liquid core of a neutron star and so determines the rate at which magnetic flux can be expelled from the core to the crust. In the earliest and most active phases of the anomalous X-ray pulsars and soft-gamma repeaters, the rates are low and consistent with a large fraction of the active crustal flux not linking the core. If normal neutrons are present in an appreciable core matter-density interval, the spectral flow force limits flux expulsion in cases of rapid spin-down, such as in the Crab pulsar or in the propeller phase of binary systems.Comment: Additional references and extended explanation: to be published in Monthly Notices of the Royal Astronomical Societ

show abstract

“…Likewise, the effective length scale d P of the pinning interaction is expected to be of the order of the coherence length ξ p or the London penetration depth λ p of the proton superconductor for the above two mechanisms, respectively. The effective pinning force (per intersection) f P = E P d P is therefore roughly the same for the two interaction mechanisms, since the value of E P due to the magnetic interaction is larger than that of the density perturbation by the same ratio as the inverse of their corresponding d P values, i.e., λ p ξ p ∼ 10 (Muslimov & Tsygan 1985;Sauls 1989;Jones 1991aJones , 2006.…”

Section: Introductionmentioning

confidence: 96%

Rotational Coupling of the Pinned Core Superfluid

Jahanmiri

2010

ApJ

View full text Add to dashboard Cite

The effects of pinning between fluxoids and vortices in the core of a neutron star on the dynamics of the core neutron superfluid are considered. The pinning impedes, but does not absolutely block, any radial as well as azimuthal motion of the neutron vortices with respect to the lattice of fluxoids. The timescale for the coupling of rotation of the core superfluid to the rest of the star is calculated, allowing for the effect of the finite frictional force on the neutron vortices due to their pinning with the fluxoids. This turns out to be the dominant mechanism for the coupling of the core of a neutron star to its crust, as compared to the role of electron scattering, for most cases of interest. Furthermore, different behaviors for the post-glitch response of the core superfluid are distinguished that might be tested against the relevant observational data. Also, a conceptually important case (and controversial too, in the earlier studies on the role of the crustal superfluid) is realized where a superfluid may remain decoupled in spite of a spinning-up of its vortices.

show abstract

Type II superconductivity and magnetic flux transport in neutron stars

Cited by 37 publications

References 24 publications

Post-glitch exponential relaxation of radio pulsars and magnetars in terms of vortex creep across flux tubes

Post-glitch exponential relaxation of radio pulsars and magnetars in terms of vortex creep across flux tubes

Fermion zero-mode influence on neutron-star magnetic field evolution

Rotational Coupling of the Pinned Core Superfluid

Contact Info

Product

Resources

About