Across the soft gamma-ray regime: utilizing simultaneous detections in the Compton Spectrometer and Imager (COSI) and the Background and Transient Observer (BTO) to understand astrophysical transients

TL;DR

This paper discusses the upcoming COSI and BTO gamma-ray missions, highlighting their combined capabilities for detecting and analyzing astrophysical transients like gamma-ray bursts and magnetar flares, with expected high detection rates.

Contribution

It introduces the BTO instrument's spectral extension to COSI, enabling comprehensive transient analysis across a broad energy range with simulated detection estimates.

Findings

BTO will detect approximately 150 gamma-ray bursts annually.

Simulations show BTO's effectiveness in analyzing gamma-ray bursts and magnetar flares.

Shared data from COSI and BTO will improve understanding of transient phenomena.

Abstract

The Compton Spectrometer and Imager (COSI) is a NASA funded Small Explorer (SMEX) mission slated to launch in 2027. COSI will house a wide-field gamma-ray telescope designed to survey the entire sky in the 0.2--5 MeV range. Using germanium detectors, the instrument will provide imaging, spectroscopy, and polarimetry of astrophysical sources with excellent energy resolution and degree-scale localization capabilities. In addition to the main instrument, COSI will fly with a student collaboration project known as the Background and Transient Observer (BTO). BTO will extend the COSI bandpass to energies lower than 200 keV, thus enabling spectral analysis across the shared band of 30 keV--2 MeV range. The BTO instrument will consist of two NaI scintillators and student-designed readout electronics. Using spectral information from both the COSI and BTO instruments, physics such as the energy peak turnover in gamma-ray bursts, the characteristics of magnetar flares, and the event frequency of a range of transient phenomena will be constrained. In this paper, we present the expected science returnables from BTO and comment on the shared returnables from the COSI and BTO missions. We include simulations of gamma-ray bursts, magnetar giant flares, and terrestrial gamma-ray flashes using BTO's spectral response. Additionally, we estimate BTO's gamma-ray burst detection rate and find that BTO will detect ~150 gamma-ray bursts per year, with most of these events being long bursts.