Precise Parameters for Two LISA Sources

TL;DR

This paper refines the parameters of two white dwarf binaries to improve their use as LISA verification sources, demonstrating how electromagnetic data enhances gravitational wave detection prospects.

Contribution

Provides precise electromagnetic parameters for two white dwarf binaries, improving LISA detectability predictions and emphasizing multi-messenger observational strategies.

Findings

Refined orbital and physical parameters for both systems.

Electromagnetic priors improve gravitational wave signal recovery.

Enhanced detection efficiency with multi-messenger data integration.

Abstract

We present precise parameters for two compact double white dwarf binaries, SDSS J232230.20+050942.0 (J2322+0509) and SDSS J063449.92+380352.2 (J0634+3803), with orbital periods of 20 and 26.5 minutes, respectively. These systems will serve as verification sources for the Laser Interferometer Space Antenna (LISA). To significantly improve the electromagnetic (EM) constraints on these two systems and the LISA detectability predictions, we conducted spectroscopic follow-up observations using HST/STIS, Keck I/LRIS, and Keck II/ESI. Our analysis significantly improves the temperature, surface gravity, and mass constraints for both primary and secondary components in J2322+0509, as well as dynamical properties such as radial velocities and orbital periods in both systems. For J2322+0509, we derive an updated inclination of $i$ = 25$^{+4.5}_{-3.0}$ deg, while for J0634+3803, we obtain $i$ = 43$^{+7.0}_{-5.6}$ deg. We assess the detectability of these sources using LDASOFT. Incorporating EM priors on inclination significantly enhances the gravitational wave signal recovery, reducing uncertainties in amplitude by a factor of 2-4 and shortening the detection time by up to a few months. Our results underscore the importance of multi-messenger observations in characterizing double white dwarf binaries and maximizing LISA's early scientific capabilities.