Chaotic migration of LISA Extreme Mass Ratio Inspirals in a turbulent accretion disk: effect on waveform de-phasing

Abstract

Gravitational wave (GW) detector LISA will observe near-coalescence extreme mass ratio inspirals (EMRIs), which typically form in galactic central accretion disks. Gas torques on EMRI will alter its GW-driven inspiral trajectory from the vacuum expectation, leading to potentially LISA-observable GW dephasing ( gas). Most studies compute gas for a thin, laminar disk, with negligible flow turbulence, where the disk exerts a fairly well-understood linear torque (T lin). However, these disks must be turbulent due to magneto-rotational instability in the inner regions. Hence, we present a proof-of-concept general, agnostic prescription for the turbulent torque (T turb) acting on an EMRI by modeling it as a Gaussian distribution around T lin, based on recent advances from a global hydrodynamical (HD) study. We compute gas for the ``golden'' circular EMRI with total source mass M=106~ M and mass ratio q=5×10-5 in its final four-year evolution at redshift z=0.276 and signal-to-noise ratio (SNR) =50 by varying Eddington ratio f Edd, turbulence normalization C (=~360 in the aforementioned HD study), disk aspect ratio h0, and turbo-viscous coefficient α in a reasonable parameters space. We find that for f Edd0.3, C300, h00.03, and α0.1, gas-induced dephasings are unobservable if only considering T lin but could become detectable ( gas>8/SNR) if EMRIs exhibit chaotic migration due to turbulent gas flow. Hence, this work motivates running MHD simulations of accretion disks with embedded LISA EMRIs in the early in-spiral phase over long enough timescales to understand the evolution of their orbital elements and the imprint of the turbulent environment on their gravitational waveforms.