Design and preliminary performance study of the broad-band spectrometer detector for POLAR-2

TL;DR

The paper presents the design and simulation-based performance evaluation of a broad-band spectrometer detector for POLAR-2, aimed at precise GRB localization and spectral measurements to enhance polarization studies.

Contribution

It introduces a novel BSD instrument with coded-aperture imaging and pixelated scintillators, and evaluates its expected scientific performance through simulations and calibration tests.

Findings

Achieves ~1.5° localization accuracy for faint GRBs

Operates effectively in 10-1000 keV energy range

Moderate capability for GRB polarimetry at several hundred keV

Abstract

POLAR-2, the successor of the POLAR experiment aboard China's Tiangong-2 space lab, is set to be deployed on the China Space Station. The POLAR-2 mission aims to conducting high-precision polarization measurements of high-energy transients with a primary focus on Gamma-Ray Bursts (GRBs), following POLAR's pioneering accurate polarization measurements of GRB prompt emission. One of the key advancements in POLAR-2 is the inclusion of a dedicated Broad-band Spectrometer Detector (BSD) instrument, designed to provide precise measurements of GRB location and spectral parameters, which are critical inputs for accurate polarization analysis of POLAR-2's dedicated High-energy Polarimetry Detector (HPD), which is made of plastic scintillator bars array. BSD employs a coded-aperture mask imaging technique and pixelated GAGG scintillation crystals, offering a wide half-coded field of view of ~132{\deg} x 125{\deg} and an operational energy range of 10-1000 keV. Simulation results indicate that the instrument can achieve a localization accuracy of approximately 1.5{\deg} for faint GRBs similar to GRB 170817A, satisfying the core requirements of GRB polarimetry with HPD. BSD also has moderate capability for GRB polarimetry, particularly at several hundred keV energy. This paper outlines the preliminary design of BSD and presents an overall evaluation of its expected scientific performance, based on extensive Monte Carlo simulations and preliminary ground-based calibration tests.