The radiative efficiency of neutron stars at low-level accretion

TL;DR

This paper investigates the radiative efficiency of neutron stars with advection-dominated accretion flows at low luminosities, revealing it is much lower than previously assumed, which affects accretion rate estimates and explains observed X-ray pulsations.

Contribution

It provides a detailed analysis of the radiative efficiency of ADAF accretion onto neutron stars, showing it is significantly lower than standard estimates and impacts interpretations of X-ray luminosity and pulsations.

Findings

Radiative efficiency of NSs with ADAF is much lower than 0.2.

Calculated accretion rates based on X-ray luminosity underestimate the true accretion rates.

The ADAF model can explain millisecond X-ray pulsations at low luminosities.

Abstract

When neutrons star low-mass X-ray binaries (NS-LMXBs) are in the low-level accretion regime (i.e., $L_{\rm X}\lesssim 10^{36}\ \rm erg\ s^{-1}$), the accretion flow in the inner region around the NS is expected to be existed in the form of the hot accretion flow, e.g., the advection-dominated accretion flow (ADAF) as that in black hole X-ray binaries. Following our previous studies in Qiao $\&$ Liu 2020a and 2020b on the ADAF accretion around NSs, in this paper, we investigate the radiative efficiency of NSs with an ADAF accretion in detail, showing that the radiative efficiency of NSs with an ADAF accretion is much lower than that of $\epsilon \sim {\dot M GM\over R_{*}}/{\dot M c^2}\sim 0.2$ despite the existence of the hard surface. As a result, given a X-ray luminosity $L_{\rm X}$ (e.g., between 0.5 and 10 keV), $\dot M$ calculated by $\dot M=L_{\rm X}{R_{*}\over {GM}}$ is lower than the real $\dot M$ calculated within the framework of the ADAF accretion. The real $\dot M$ can be more than two orders of magnitude higher than that of calculated by $\dot M=L_{\rm X}{R_{*}\over {GM}}$ with appropriate model parameters. Finally, we discuss that if applicable, the model of ADAF accretion around a NS can be applied to explain the observed millisecond X-ray pulsation in some NS-LMXBs (such as PSR J1023+0038, XSS J12270-4859 and IGR J17379-3747) at a lower X-ray luminosity of a few times of $10^{33}\ \rm erg\ s^{-1}$, since at this X-ray luminosity the calculated $\dot M$ with the model of ADAF accretion can be high enough to drive a fraction of the matter in the accretion flow to be channelled onto the surface of the NS forming the X-ray pulsation.