Lucas M. B. Alves scite author profile

Gravitational waves from neutron star mergers have long been considered a promising way to measure the Hubble constant, H0, which describes the local expansion rate of the Universe. While black hole mergers are more abundantly observed, their expected lack of electromagnetic emission and poor gravitational-wave localization makes them less suited for measuring H0. Black hole mergers within the disks of Active Galactic Nuclei (AGN) could be an exception. Accretion from the AGN disk may produce an electromagnetic signal, pointing observers to the host galaxy. Alternatively, the low number density of AGNs could help identify the host galaxy of 1 − 5% of mergers. Here we show that black hole mergers in AGN disks may be the most sensitive way to determine H0 with gravitational waves. If 1% of LIGO/Virgo's observations occur in AGN disks with identified host galaxies, we could measure H0 with 1% uncertainty within five years, likely beyond the sensitivity of neutrons star mergers.

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Multimessenger emission from tidal waves in neutron star oceans

Sullivan

Alves

Spence

et al. 2023

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Neutron stars in astrophysical binary systems represent exciting sources for multi-messenger astrophysics. A potential source of electromagnetic transients from compact binary systems is the neutron star ocean, the external fluid layer encasing a neutron star. We present a groundwork study into tidal waves in neutron star oceans and their consequences. Specifically, we investigate how oscillation modes in neutron star oceans can be tidally excited during compact binary inspirals and parabolic encounters. We find that neutron star oceans can sustain tidal waves with frequencies between 0.01 − 20 Hz. Our results suggest that tidally resonant neutron star ocean waves may serve as a never-before studied source of precursor electromagnetic emission prior to neutron star-black hole and binary neutron star mergers. If accompanied by electromagnetic flares, tidally resonant neutron star ocean waves, whose energy budget can reach 1046 erg, may serve as early warning signs (≳ 1 minute before merger) for compact binary mergers. Similarly, excited ocean tidal waves will coincide with neutron star parabolic encounters. Depending on the neutron star ocean model and a flare emission scenario, tidally resonant ocean flares may be detectable by Fermi and NuSTAR out to ≳ 100 Mpc with detection rates as high as ∼7 yr−1 for binary neutron stars and ∼0.6 yr−1 for neutron star-black hole binaries. Observations of emission from neutron star ocean tidal waves along with gravitational waves will provide insight into the equation of state at the neutron star surface, the composition of neutron star oceans and crusts, and neutron star geophysics.

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Multi-messenger Emission from Tidal Waves in Neutron Star Oceans

Sullivan¹,

Alves²,

Spence³

et al. 2022

Preprint

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Astrophysical binary systems including neutron stars represent exciting sources for multimessenger astrophysics. A little considered source of electromagnetic transients accompanying compact binary systems is a neutron star ocean, the external fluid layer encasing a neutron star. We present a groundwork study into tidal waves in neutron star oceans and their consequences. Specifically, we investigate how oscillation modes in neutron star oceans can be tidally excited during compact binary inspirals and parabolic encounters to produce tidal waves. We find that neutron star oceans can sustain tidal waves with frequencies under 100 mHz. Our results suggest that resonant neutron star ocean tidal waves may serve as a never-before studied source for precursor electromagnetic emission prior to neutron star-black hole and binary neutron star mergers. Resonant neutron star ocean tidal waves, whose energy budget can reach 10 45 erg, may serve as very early warning signs (∼ 1 − 10 yr before merger) for compact binary mergers if accompanied by electromagnetic flares. Similarly, excited ocean tidal waves will coincide with neutron star parabolic encounters. Depending on the neutron star ocean model and a flare emission scenario, flares may be detectable by Fermi and NuSTAR out to ∼ 100 Mpc with detection rates as high as ∼ 7 yr −1 for binary neutron stars and ∼ 0.6 yr −1 for neutron star-black hole binaries. Observations of emission from neutron star ocean tidal waves along with gravitational waves will provide insight into the equation of state at the neutron star surface, the composition of neutron star oceans and crusts, and neutron star geophysics.

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Lucas M. B. Alves

Determining the Hubble Constant with Black Hole Mergers in Active Galactic Nuclei

Multimessenger emission from tidal waves in neutron star oceans

Multi-messenger Emission from Tidal Waves in Neutron Star Oceans

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