Pulsars, transients and relativistic astrophysics

A Strong Jet Signature in the Late-Time Lightcurve of GW170817

(2018)

Authors:

KP Mooley, DA Frail, D Dobie, E Lenc, A Corsi, K De, AJ Nayana, S Makhathini, I Heywood, T Murphy, DL Kaplan, P Chandra, O Smirnov, E Nakar, G Hallinan, F Camilo, R Fender, S Goedhart, P Groot, MM Kasliwal, SR Kulkarni, PA Woudt

Ultra-high energy cosmic rays from shocks in the lobes of powerful radio galaxies

(2018)

Authors:

James H Matthews, Anthony R Bell, Katherine M Blundell, Anabella T Araudo

Signatures of an eruptive phase before the explosion of the peculiar core-collapse SN 2013gc

Monthly Notices of the Royal Astronomical Society Oxford University Press (OUP) 482:2 (2018) 2750-2769

Authors:

Andrea Reguitti, A Pastorello, G Pignata, S Benetti, E Cappellaro, M Turatto, C Agliozzo, F Bufano, NI Morrell, F Olivares E., DE Reichart, JB Haislip, V Kouprianov, SJ Smartt, S Ciroi

Black hole mergers from an evolving population of globular clusters

Phys. Rev. Lett. 121 (2018) 161103-161103

Authors:

Giacomo Fragione, Bence Kocsis

Abstract:

The high rate of black hole (BH) mergers detected by LIGO/Virgo opened questions on their astrophysical origin. One possibility is the dynamical channel, in which binary formation and hardening is catalyzed by dynamical encounters in globular clusters (GCs). Previous studies have shown that the BH merger rate from the present day GC density in the Universe is lower than the observed rate. In this \textit{Letter}, we study the BH merger rate by accounting for the first time for the evolution of GCs within their host galaxies. The mass in GCs was initially $\sim 8\times$ higher, which decreased to its present value due to evaporation and tidal disruption. Many BH binaries that were ejected long before their merger, originated in GCs that no longer exist. We find that the comoving merger rate in the dynamical channel from GCs varies between $18$ to $35\,{\rm Gpc}^{-3}\,{\rm yr}^{-1}$ between redshift $z=0.5$ to $2$, and the total rate is $1$, $5$, $24$ events per day within $z=0.5$, $1$, and $2$, respectively. The cosmic evolution and disruption of GCs systematically increases the present-day merger rate by a factor $\sim 2$ relative to isolated clusters. Gravitational wave detector networks offer an unique observational probe of the initial number of GC populations and their subsequent evolution across cosmic time.

Constraining Stellar-mass Black Hole Mergers in AGN Disks Detectable with LIGO

ASTROPHYSICAL JOURNAL American Astronomical Society 866:1 (2018) ARTN 66

Authors:

Barry McKernan, KE Saavik Ford, J Bellovary, Nwc Leigh, Z Haiman, B Kocsis, W Lyra, M-M Mac Low, B Metzger, M O'Dowd, S Endlich, Dj Rosen

Abstract:

© 2018. The American Astronomical Society. All rights reserved.. Black hole (BH) mergers detectable with the Laser Interferometer Gravitational-wave Observatory (LIGO) can occur in active galactic nucleus (AGN) disks. Here we parameterize the merger rates, the mass spectrum, and the spin spectrum of BHs in AGN disks. The predicted merger rate spans ∼10-3-104 Gpc-1 yr-1, so upper limits from LIGO (<212 Gpc-1 yr-1) already constrain it. The predicted mass spectrum has the form of a broken power law, consisting of a pre-existing BH power-law mass spectrum and a harder power-law mass spectrum resulting from mergers. The predicted spin spectrum is multipeaked with the evolution of retrograde spin BHs in the gas disk playing a key role. We outline the large uncertainties in each of these LIGO observables for this channel and we discuss ways in which they can be constrained in the future.