Constraints on the nuclear equation of state and the neutron star structure from crustal torsional oscillations

TL;DR

This paper constrains the nuclear symmetry energy and neutron star structure by analyzing torsional oscillations in neutron star crusts, considering cylindrical nuclei phases and matching observed QPOs.

Contribution

It introduces a new parameter $oldsymbol{ u}$ to relate torsional oscillation overtones to nuclear matter properties, refining constraints on neutron star models.

Findings

Constraints on the slope parameter $L$ of nuclear symmetry energy ($58-73$ MeV).

Identification of the 1st overtone frequency with observed high-frequency QPOs.

Neutron star models favoring low mass and large radius consistent with empirical nuclear data.

Abstract

We systematically examine torsional shear oscillations of neutron star crusts by newly taking into account the possible presence of the phase of cylindrical nuclei. In this study, we neglect an effect of magnetic fields, under which the shear oscillations can be damped by the magnetic interaction. First, by identifying the low frequency quasi-periodic oscillations (QPOs) observed in the soft-gamma repeaters (SGRs) as the fundamental torsional oscillations, we constrain the slope parameter of the nuclear symmetry energy, $L$, for reasonable values of the star's mass $M$ and radius $R$. Meanwhile, we find that the 1st overtone of torsional oscillations obtained for given $M$ and $R$ can be expressed well as a function of a new parameter $\varsigma\equiv (K_0^4 L^5)^{1/9}$, where $K_0$ is the incompressibility of symmetric nuclear matter. Assuming that the lowest of the QPO frequencies above 500 Hz observed in SGR 1806-20 comes from the 1st overtone, we can constrain the value of $\varsigma$. Then, for each neutron star model, such a value of $L$ as can be obtained from the observed low frequency QPOs translates to the optimal value of $K_0$ via the above constraint on $\varsigma$. Finally, its consistency with allowed values of $K_0$ from empirical giant monopole resonances leads to neutron star models with relatively low mass and large radius, which are qualitatively similar to the prediction in earlier investigations. This result suggests that $L\simeq 58-73$ MeV, even when uncertainties in the neutron superfluid density inside the phase of cylindrical nuclei are allowed for.