General relativistic spectra from accretion disks around rotating neutron s
tars in the appropriate spacetime geometry for several different equations
of state, spin rates, and masses of the compact object have been computed.
The analysis involves the computation of the relativistically corrected rad
ial temperature profiles and the effect of Doppler and gravitational redshi
fts on the spectra. Light-bending effects have been omitted for simplicity.
The relativistic spectrum is compared with the Newtonian one, and it is sh
own that the difference between the two is primarily a result of the differ
ent radial temperature profiles for the relativistic and Newtonian disk sol
utions. To facilitate direct comparison with observations, a simple empiric
al function has been presented which describes the numerically computed rel
ativistic spectra well. This empirical function (which has three parameters
including normalization) also describes the Newtonian spectrum adequately.
Thus, the function can in principle be used to distinguish between the two
. In particular, the best-fit value of one of the parameters (beta -paramet
er) approximate to0.4 for the Newtonian case, while it ranges from 0.1 to 0
.35 for the relativistic case depending upon the inclination angle, equatio
n of state (EOS), spin rate, and mass of the neutron star. Constraining thi
s parameter by fits to future observational data of X-ray binaries will ind
icate the effect of strong gravity in the observed spectrum.