Measuring tides and binary parameters from gravitational wave data and eclipsing timings of detached white dwarf binaries

Abstract

The discovery of the most compact detached white dwarf (WD) binary SDSS J065133.33+284423.3 has been discussed in terms of probing the tidal effects in white dwarfs. This system is also a verification source for the space-based gravitational wave (GW) detector, evolved Laser Interferometer Space Antenna (eLISA) which will observe short-period compact Galactic binaries with Porb 5 hrs. We address the prospects of doing tidal studies using eLISA binaries by showing the fractional uncertainties in the orbital decay rate and the rate of that decay, f, f expected from both the GW and EM data for some of the high-f binaries. We find that f and f can be measured using GW data only for the most massive WD binaries observed at high-frequencies. Form timing the eclipses for 10 years, we find that f can be known to 0.1% for J0651. We find that from GW data alone, measuring the effects of tides in binaries is (almost) impossible. We also investigate the improvement in the knowledge of the binary parameters by combining GW amplitude and inclination with EM data with and without f. In our previous work we found that EM data on distance constrained 2-σ uncertainty in chirp mass to 15-25% whereas adding f reduces it to 0.11%. EM data on f also constrains 2-σ uncertainty in distance to 35%-19%. EM data on primary mass constrains the secondary mass m2 to factors of 2 to 40% whereas adding f reduces this to 25%. And finally using single-line spectroscopic constrains 2-σ uncertainties in both the m2, d to factors of 2 to 40%. Adding EM data on f reduces these 2-σ uncertainties to ≤ 25% and 6%-19% respectively. Thus we find that EM measurements of f and radial velocity will be valuable in constraining binary parameters.