SVOM/VT: Instrument Overview, Science Objectives, and First-Year Performance

TL;DR

The SVOM/VT is a dual-band optical telescope designed for detecting and studying gamma-ray burst counterparts, demonstrating high sensitivity, rapid response, and effective performance in its first year in orbit.

Contribution

This paper details the VT's design, scientific goals, observing strategies, data pipelines, and first-year performance, highlighting its superior detection rate and role in high-redshift GRB identification.

Findings

Sensitivity of 22.5 AB mag in orbit, extendable to 24 AB mag with stacking

Detected over 100 GRBs in first year with 80% detection rate

Enabled identification of high-redshift GRB 250314A at z=7.3

Abstract

The 44-cm Visible Telescope (VT) aboard the Space-based Variable Objects Monitor (SVOM) is a dual-band (400-650 nm and 650-1000 nm) instrument designed to detect and characterize the optical counterparts of gamma-ray bursts (GRBs) and other high-energy transients. This paper presents the VT's design, scientific objectives, observing strategies, and both space- and ground-based data processing pipelines, along with its first-year in-orbit performance. In-orbit commissioning tests confirm a sensitivity of 22.5 AB mag (300 s exposure), extendable to $\sim\!24$ AB mag through stacking. This performance enables the VT to monitor over 100 GRBs in its first year with an exceptional $\sim\!80\%$ detection rate for \textit{SVOM}/ECLAIRS-triggered bursts and ToO-observed bursts from other missions (e.g., \textit{Swift, Fermi, Einstein Probe (EP)}), outperforming \textit{Swift}/UVOT's $\sim\!40\%$ detection rate. Beyond its exceptional detection efficiency, the VT played a key role in identifying high-redshift GRBs-most notably GRB 250314A (z = 7.3). Its deep upper limits at long wavelengths (up to 1 $\mu$m) were pivotal in guiding follow-up observations with large ground-based telescopes, enabling crucial near-infrared (NIR) detections. With its rapid response, deep sensitivity, and real-time processing capabilities, the VT is a key instrument for GRB research in \textit{SVOM}-era, enabling critical studies of GRB optical afterglows, circumburst environments, relativistic jet dynamics, and the origins of optically dark bursts.