Modeling transient resonances in extreme-mass-ratio inspirals

TL;DR

This paper develops an efficient model for tidal resonances in extreme-mass-ratio inspirals, crucial for accurate gravitational wave signal analysis and parameter estimation in space-based detectors like LISA.

Contribution

It introduces a generic resonance modeling approach incorporating multiple resonance combinations and validates a simplified step function method against numerical evolution.

Findings

The simplified resonance jump model has minimal error within realistic parameter ranges.

Fisher matrix analysis shows potential for precise parameter estimation despite resonances.

The method can be extended to self-force resonance modeling for EMRI waveforms.

Abstract

Extreme-mass-ratio inspirals are one of the most exciting and promising target sources for space-based interferometers (such as LISA, TianQin). The observation of their emitted gravitational waves will offer stringent tests on general theory of relativity, and provide a wealth of information about the dense environment in galactic centers. To unlock such potential, it is necessary to correctly characterize EMRI signals. However, resonances are a phenomena that occurs in EMRI systems and can impact parameter inference, and therefore the science outcome, if not properly modeled. Here, we explore how to model resonances and develop an efficient implementation. Our previous work has demonstrated that tidal resonances induced by the tidal field of a nearby astrophysical object alters the orbital evolution, leading to a significant dephasing across observable parameter space. Here, we extensively explore a more generic model for the tidal perturber with additional resonance combinations, to study the dependence of resonance strength on the intrinsic orbital and tidal parameters. To analyze the resonant signals, accurate templates that correctly incorporate the effects of the tidal field are required. The evolution through resonances is obtained using a step function, whose amplitude is calculated using an analytic interpolation of the resonance jumps. We benchmark this procedure by comparing our approximate method to a numerical evolution. We find that there is no significant error caused by this simplified prescription, as far as the astronomically reasonable range in the parameter space is concerned. Further, we use Fisher matrices to study both the measurement precision of parameters and the systematic bias due to inaccurate modeling. Modeling of self-force resonances can also be carried out using the implementation presented in this study, which will be crucial for EMRI waveform modeling.