Self-Lensing Signals in Binary Systems Containing White Dwarfs with Neutron star or Stellar-mass Black hole Companions

Abstract

Light curves from binary systems containing white dwarfs with neutron star or stellar-mass black hole companions (WD+NS and WD+BH) with edge-on orbital planes potentially show self-lensing/eclipsing signals. Here, we evaluate the properties and detectability of these signals in the NASA's Transiting Exoplanet Survey Satellite (TESS), and the Nancy Grace Roman Space Telescope (Roman) observations. WD+NS systems with orbital periods T25~days mostly have considerable finite-source sizes with the normalized source radii 1. WD+BH systems with T3 days have 1, and 0.01 for BHs with a few tens solar-mass. Our analytical calculations show the probabilities of occurring self-lensing signals in WD+NS and WD+BH systems are 10-3,~10-2, and maximize for systems with low-mass WDs revolving massive NSs/BHs. We simulate their light curves and generate synthetic data for them by applying the observing protocols of these two satellites. We assume self-lensing signals are detectable if (i) 1≤ T≤ Tobs (where Tobs=62~and~27.4 days are the Roman and TESS continuous observing windows), (ii) SNR3,~6, their signals are (iii) deeper than twice the photometric error, and (iv) covered by at least one datum. Systems with detectable self-lensing signals in the TESS and Roman observations on average have small inclination angles i0.2, with the orbital periods 6,~19~days, and their signals last [6,~30]~minutes. The TESS and Roman efficiencies for detecting these signals are 2-6×10-4 and 2-12×10-10. Although detecting these self-lensing signals by Roman is impossible, the TESS telescope potentially manifests at least one self-lensing signal due to these binary systems, if 8\%,~and~3\% of WDs have NS and BH companions.