Deviations from chemical equilibrium due to spin-down as an internal heat source in neutron stars

Reisenegger, Andreas

doi:10.1086/175480

Cited by 158 publications

(247 citation statements)

References 28 publications

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“…These estimates show that τ cool is of the same order of magnitude as τ rel for both cases of the slow and fast cooling, with τ rel being several times shorter. Using this fact Reisenegger (1995) concluded that the beta relaxation occurs much faster than the cooling. From our point of view, the difference by a factor of several is not decisive and the non-equilibrium state may persist for some time, i.e, the value of ξ may decrease slowly as the cooling proceeds.…”

Section: Non-equilibrium Urca Processesmentioning

confidence: 98%

“…It is much longer than the typical timescale ∼ 10 −3 s, corresponding to the local compression of matter during the collapse of a neutron star into the black hole (Gourgoulhon and Haensel 1993) or to the radial pulsations of the neutron star. In sufficiently old pulsars, τ rel can also be much longer than the timescale of the local compression of matter, implied by the slowing-down of pulsar rotation (Reisenegger 1995). In all these cases, one has to consider the Urca processes in neutron star matter out of beta equilibrium (Haensel 1992, Reisenegger 1995.…”

Section: Non-equilibrium Urca Processesmentioning

confidence: 99%

“…In sufficiently old pulsars, τ rel can also be much longer than the timescale of the local compression of matter, implied by the slowing-down of pulsar rotation (Reisenegger 1995). In all these cases, one has to consider the Urca processes in neutron star matter out of beta equilibrium (Haensel 1992, Reisenegger 1995.…”

Section: Non-equilibrium Urca Processesmentioning

confidence: 99%

“…In the absence of beta equilibrium, there is a finite difference of the chemical potentials, δµ ≡ µ n − µ p − µ e = 0 (our definition of δµ agrees with that of Haensel 1992, and differs in sign from that of Reisenegger 1995). To be specific, we set δµ > 0, which means an excess of neutrons and deficit of protons and electrons with respect to the fully equilibrium values.…”

Section: Non-equilibrium Urca Processesmentioning

confidence: 99%

“…However, the chemical heating term ∆Γ δµ prevails for ξ > ∼ 5.5, leading to the net heating of the matter. Such a situation is relevant for the neutron star collapse (Gourgoulhon and Haensel 1993), and for the interplay of cooling and spin-down of older pulsars (Reisenegger 1995).…”

Section: Non-equilibrium Urca Processesmentioning

confidence: 99%

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Neutrino emission from neutron stars

Kaminker²,

et al. 2001

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We review the main neutrino emission mechanisms in neutron star crusts and cores. Among them are the well-known reactions such as the electron-positron annihilation, plasmon decay, neutrino bremsstrahlung of electrons colliding with atomic nuclei in the crust, as well as the Urca processes and neutrino bremsstrahlung in nucleon-nucleon collisions in the core. We emphasize recent theoretical achievements, for instance, band structure effects in neutrino emission due to scattering of electrons in Coulomb crystals of atomic nuclei. We consider the standard composition of matter (neutrons, protons, electrons, muons, hyperons) in the core, and also the case of exotic constituents such as the pion or kaon condensates and quark matter. We discuss the reduction of the neutrino emissivities by nucleon superfluidity, as well as the specific neutrino emission produced by Cooper pairing of the superfluid particles. We also analyze the effects of strong magnetic fields on some reactions, such as the direct Urca process and the neutrino synchrotron emission of electrons. The results are presented in the form convenient for practical use. We illustrate the effects of various neutrino reactions on the cooling of neutron stars. In particular, the neutrino emission in the crust is critical in setting the initial thermal relaxation between the core and the crust. Finally, we discuss the prospects of exploring the properties of supernuclear matter by confronting cooling simulations with observations of the thermal radiation from isolated neutron stars.

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Section: Non-equilibrium Urca Processesmentioning

confidence: 98%

Section: Non-equilibrium Urca Processesmentioning

confidence: 99%

Section: Non-equilibrium Urca Processesmentioning

confidence: 99%

Section: Non-equilibrium Urca Processesmentioning

confidence: 99%

Section: Non-equilibrium Urca Processesmentioning

confidence: 99%

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Neutrino emission from neutron stars

Kaminker²,

et al. 2001

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Magnetic field evolution in neutron stars

Reisenegger

2007

Astron Nachr

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Neutron stars contain persistent, ordered magnetic fields that are the strongest known in the Universe. However, their magnetic fluxes are similar to those in magnetic A and B stars and white dwarfs, suggesting that flux conservation during gravitational collapse may play an important role in establishing the field, although it might also be modified substantially by early convection, differential rotation, and magnetic instabilities. The equilibrium field configuration, established within hours (at most) of the formation of the star, is likely to be roughly axisymmetric, involving both poloidal and toroidal components. The stable stratification of the neutron star matter (due to its radial composition gradient) probably plays a crucial role in holding this magnetic structure inside the star. The field can evolve on long time scales by processes that overcome the stable stratification, such as weak interactions changing the relative abundances and ambipolar diffusion of charged particles with respect to neutrons. These processes become more effective for stronger magnetic fields, thus naturally explaining the magnetic energy dissipation expected in magnetars, at the same time as the longer-lived, weaker fields in classical and millisecond pulsars.Comment: To appear in Astronomische Nachrichten (Astronomical Notes) as part of the Proceedings of the 5th Potsdam Thinkshop, "Meridional Circulation, Differential Rotation, Solar and Stellar Activity", held 2007 June 24-29. 5 pages, no figure

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Studying millisecond pulsars in X-rays

Zavlin¹

2007

Isolated Neutron Stars: From the Surface to the Interior

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Deviations from chemical equilibrium due to spin-down as an internal heat source in neutron stars

Cited by 158 publications

References 28 publications

Neutrino emission from neutron stars

Neutrino emission from neutron stars

Magnetic field evolution in neutron stars

Studying millisecond pulsars in X-rays

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