An Infrared Search for Kilonovae with the WINTER Telescope. I. Binary Neutron Star Mergers

TL;DR

The paper introduces WINTER, a near-infrared survey instrument designed to detect kilonovae from binary neutron star mergers, demonstrating its potential effectiveness through detailed simulations of upcoming gravitational wave observing runs.

Contribution

The paper presents the design, simulation, and strategy for WINTER, a new infrared telescope dedicated to follow-up of kilonovae, including an end-to-end simulation framework for future gravitational wave events.

Findings

WINTER could independently discover up to five kilonovae during O4.

Kilonova emission lasts about twice as long in infrared as in optical.

Infrared detection extends approximately 1.5 times further than optical for red kilonovae.

Abstract

The Wide-Field Infrared Transient Explorer (WINTER) is a new 1 $\text{deg}^2$ seeing-limited time-domain survey instrument designed for dedicated near-infrared follow-up of kilonovae from binary neutron star (BNS) and neutron star-black hole mergers. WINTER will observe in the near-infrared Y, J, and short-H bands (0.9-1.7 microns, to $\text{J}_{AB}=21$ magnitudes) on a dedicated 1-meter telescope at Palomar Observatory. To date, most prompt kilonova follow-up has been in optical wavelengths; however, near-infrared emission fades more slowly and depends less on geometry and viewing angle than optical emission. We present an end-to-end simulation of a follow-up campaign during the fourth observing run (O4) of the LIGO, Virgo, and KAGRA interferometers, including simulating 625 BNS mergers, their detection in gravitational waves, low-latency and full parameter estimation skymaps, and a suite of kilonova lightcurves from two different model grids. We predict up to five new kilonovae independently discovered by WINTER during O4, given a realistic BNS merger rate. Using a larger grid of kilonova parameters, we find that kilonova emission is $\approx$2 times longer-lived and red kilonovae are detected $\approx$1.5 times further in the infrared than in the optical. For 90% localization areas smaller than 150 (450) $\rm{deg}^{2}$, WINTER will be sensitive to more than 10% of the kilonova model grid out to 350 (200) Mpc. We develop a generalized toolkit to create an optimal BNS follow-up strategy with any electromagnetic telescope and present WINTER's observing strategy with this framework. This toolkit, all simulated gravitational-wave events, and skymaps are made available for use by the community.