Context. Pulsars show a steady decrease in their rotational frequency, occasionally interrupted by sudden spin-ups called glitches, whose physical origin is still a mystery. One suggested explanation for at least the small glitches are starquakes, that is, failures of the solid neutron star crust, in which the progressive reduction in the centrifugal force deforms the star, stressing the solid until it breaks. This produces a spin-up, dissipating energy inside the star. Aims. We explore this suggestion by analyzing a mostly analytical model in order to understand the possible consequences of starquakes, particularly whether they can explain at least the small glitches. Methods. We analyze the deformations and strains produced by the decreas...
We study a class of Newtonian models for the deformations of non-magnetized neutron stars duringthei...
Crustquake events may be connected with both rapid spin-up 'glitches' within the regular slowdown of...
Mature neutron stars are expected to have several superfluid components. Strong evidence for this is...
Context. Pulsars show a steady decrease in their rotational frequency, occasionally interrupted by s...
Gravitational, magnetic and superfluid forces can stress the crust of an evolving neutron star. Frac...
Glitches – sudden increases in spin rate – are observed in many pulsars. One mechanism advanced to e...
Many different astrophysical events related to pulsars are taught to be due to starquakes, that coul...
We describe a new instability that may trigger the global unpinning of vortices in a spinning neutro...
We examine the thermal and dynamical response of a neutron star to a sudden perturbation of the inne...
Many radio pulsars exhibit glitches wherein the star\u27s spin rate increases fractionally by ~10-10...
Neutron stars are the most compact known stars; their cores are of higher density than an atomic nuc...
Pulsar glitches provide a unique way to study neutron star microphysics because short post-glitch dy...
22 pages, 3 figures, LatexThe frequent glitches (sudden increases of the apparent angular velocity) ...
Accreting neutron stars (NSs) have long been considered potential continuous gravitational-wave (GW)...
We introduce a Newtonian model for the deformations of a compressible neutron star that goes beyond ...
We study a class of Newtonian models for the deformations of non-magnetized neutron stars duringthei...
Crustquake events may be connected with both rapid spin-up 'glitches' within the regular slowdown of...
Mature neutron stars are expected to have several superfluid components. Strong evidence for this is...
Context. Pulsars show a steady decrease in their rotational frequency, occasionally interrupted by s...
Gravitational, magnetic and superfluid forces can stress the crust of an evolving neutron star. Frac...
Glitches – sudden increases in spin rate – are observed in many pulsars. One mechanism advanced to e...
Many different astrophysical events related to pulsars are taught to be due to starquakes, that coul...
We describe a new instability that may trigger the global unpinning of vortices in a spinning neutro...
We examine the thermal and dynamical response of a neutron star to a sudden perturbation of the inne...
Many radio pulsars exhibit glitches wherein the star\u27s spin rate increases fractionally by ~10-10...
Neutron stars are the most compact known stars; their cores are of higher density than an atomic nuc...
Pulsar glitches provide a unique way to study neutron star microphysics because short post-glitch dy...
22 pages, 3 figures, LatexThe frequent glitches (sudden increases of the apparent angular velocity) ...
Accreting neutron stars (NSs) have long been considered potential continuous gravitational-wave (GW)...
We introduce a Newtonian model for the deformations of a compressible neutron star that goes beyond ...
We study a class of Newtonian models for the deformations of non-magnetized neutron stars duringthei...
Crustquake events may be connected with both rapid spin-up 'glitches' within the regular slowdown of...
Mature neutron stars are expected to have several superfluid components. Strong evidence for this is...