The Radiative Efficiency of a Radiatively Inefficient Accretion Flow

A recent joint XMM-Newton/Nuclear Spectroscopic Telescope Array (NuSTAR) observation of the accreting neutron star Cen X-4 (\(L_{\rm X}\sim10^{33}{\rm~erg~s}^{-1}\)) revealed a hard power-law component (\(\Gamma\sim1\)-\(1.5\)) with a relatively low cut-off energy (~10 keV), suggesting bremsstrahlun...

Full description

Saved in:
Bibliographic Details
Published in:arXiv.org 2015-04
Main Authors: D'Angelo, C R, Fridriksson, J K, Messenger, C, Patruno, A
Format: Article
Language:English
Subjects:
Boundary layers
Bremsstrahlung
Deposition
Magnetic fields
Neutron stars
Neutrons
Potential energy
Spectroscopic telescopes
XMM (spacecraft)
Online Access:Get full text
Tags: Add Tag
No Tags, Be the first to tag this record!
Description
Summary:A recent joint XMM-Newton/Nuclear Spectroscopic Telescope Array (NuSTAR) observation of the accreting neutron star Cen X-4 (\(L_{\rm X}\sim10^{33}{\rm~erg~s}^{-1}\)) revealed a hard power-law component (\(\Gamma\sim1\)-\(1.5\)) with a relatively low cut-off energy (~10 keV), suggesting bremsstrahlung emission. The physical requirements for bremsstrahlung combined with other observed properties of Cen X-4 suggest the emission comes from a boundary layer rather than the accretion flow. The accretion flow itself is thus undetected (with an upper limit of \(L_{\rm flow}\lesssim0.3 L_{\rm X}\)). A deep search for coherent pulsations (which would indicate a strong magnetic field) places a 6 per cent upper limit on the fractional amplitude of pulsations, suggesting the flow is not magnetically regulated. Considering the expected energy balance between the accretion flow and the boundary layer for different values of the neutron star parameters (size, magnetic field, and spin) we use the upper limit on \(L_{\rm flow}\) to set an upper limit of \(\varepsilon\lesssim0.3\) for the intrinsic radiative efficiency of the accretion flow for the most likely model of a fast-spinning, non-magnetic neutron star. The non-detection of the accretion flow provides the first direct evidence that this flow is indeed 'radiatively inefficient', i.e. most of the gravitational potential energy lost by the flow before it hits the star is not emitted as radiation.
ISSN:2331-8422
DOI:10.48550/arxiv.1410.3760