Fast Methods for Computing Photometric Variability of Eccentric Binaries: Boosting, Lensing, and Variable Accretion

TL;DR

This paper introduces a fast computational method and a tool called binlite for modeling photometric variability in eccentric binary systems, incorporating effects like lensing and accretion, to aid in interpreting observational data.

Contribution

The paper presents a new rapid template generation tool for accretion variability in eccentric binaries, integrating multiple physical effects for flexible lightcurve modeling.

Findings

Binary orbital period dominates variability at high eccentricities.

The shape of accretion-rate time series varies with eccentricity.

The binlite tool generates templates in under 0.01 seconds.

Abstract

We analyze accretion-rate time series for equal-mass binaries in co-planar gaseous disks spanning a continuous range of orbital eccentricities up to 0.8, for both prograde and retrograde systems. The dominant variability timescales match that of previous investigations; the binary orbital period is dominant for prograde binaries with $e \gtrsim 0.1$, with a 5 times longer "lump" period taking over for $e\lesssim 0.1$. This lump period fades and drops from 5 times to 4.5 times the binary period as $e$ approaches 0.1, where it vanishes. For retrograde orbits, the binary orbital period dominates at $e \lesssim 0.55$ and is accompanied by a 2 times longer-timescale periodicity at higher eccentricities. The shape of the accretion-rate time series varies with binary eccentricity. For prograde systems, the orientation of an eccentric disk causes periodic trading of accretion between the binary components in a ratio that we report as a function of binary eccentricity. We present a publicly available tool, binlite, that can rapidly ($\lesssim 0.01$~sec) generate templates for the accretion-rate time series, onto either binary component, for choice of binary eccentricity below 0.8. As an example use-case, we build lightcurve models where the accretion rate through the circumbinary disk and onto each binary component sets contributions to the emitted specific flux. We combine these rest-frame, accretion-variability lightcurves with observer-dependent Doppler boosting and binary self-lensing. This allows a flexible approach to generating lightcurves over a wide range of binary and observer parameter space. We envision binlite as the access point to a living database that will be updated with state-of-the-art hydrodynamical calculations as they advance.