pith. sign in

Breaking properties of neutron star crust

3 Pith papers cite this work. Polarity classification is still indexing.

3 Pith papers citing it
abstract

The strength of neutron star crust is crucial for modelling magnetar flares, pulsar glitches and gravitational wave emission. We aim to shed some light on this problem by analysing uniaxial stretch deformation (elongation and contraction) of perfect body-centered cubic Coulomb crystals, paying special attention to the inherent anisotropy of this process. Our analysis is based on the semi-analytical approach of Baiko and Kozhberov (2017), which, for any uniform deformation, allows one to calculate, in fully non-linear regime, critical deformation parameters beyond which the lattice loses its dynamic stability. We determine critical strain, pressure anisotropy and deformation energy for any stretch direction with respect to the crystallographic axes. These quantities are shown to be strongly anisotropic: they vary by a factor of almost 10 depending on the orientation of the deformation axis. For polycrystalline crust, we argue that the maximum strain for the stretch deformation sustainable elastically is 0.04. It is lower than the breaking strain of 0.1 obtained in molecular dynamic simulations of a shear deformation by Horowitz and Kadau (2009). The maximum pressure anisotropy of polycrystalline matter is estimated to be in the range from 0.005 to 0.014 $nZ^2e^2/a$, where $n$ is the ion number density, $Ze$ is the ion charge, and $a$ is the ion-sphere radius. We discuss possible mechanisms of plastic motion and formation of large crystallites in neutron star crust as well as analyse energy release associated with breaking of such crystallites in the context of magnetic field evolution and magnetar flaring activity.

fields

astro-ph.HE 3

years

2026 3

verdicts

UNVERDICTED 3

representative citing papers

Plasticity of Neutron Star Crusts

astro-ph.HE · 2026-06-04 · unverdicted · novelty 7.0

MD simulations identify a universal post-break plastic flow in neutron star crusts at shear strains of 0.05-0.11, independent of initial crystal structure.

Crust glass formation reveals the neutron star birth properties in IGR J17480-2446

astro-ph.HE · 2026-06-20 · unverdicted · novelty 6.0

Accretion-induced failure of the neutron star crystal crust produces a glass layer that explains the observed cooling, fixes the accreted mass at 2.4e-6 solar masses, and indicates birth properties typical of recycled neutron stars, potentially from electron-capture supernova formation.

citing papers explorer

Showing 3 of 3 citing papers.

  • Plasticity of Neutron Star Crusts astro-ph.HE · 2026-06-04 · unverdicted · none · ref 20 · internal anchor

    MD simulations identify a universal post-break plastic flow in neutron star crusts at shear strains of 0.05-0.11, independent of initial crystal structure.

  • Crust glass formation reveals the neutron star birth properties in IGR J17480-2446 astro-ph.HE · 2026-06-20 · unverdicted · none · ref 136 · internal anchor

    Accretion-induced failure of the neutron star crystal crust produces a glass layer that explains the observed cooling, fixes the accreted mass at 2.4e-6 solar masses, and indicates birth properties typical of recycled neutron stars, potentially from electron-capture supernova formation.

  • Bayesian analysis of the shear modulus in the neutron-star crust astro-ph.HE · 2026-06-08 · unverdicted · none · ref 195 · internal anchor

    Bayesian modeling with informed priors reduces uncertainties in neutron-star crust shear properties, predicting torsional mode frequencies of 20-50 Hz compatible with observations.