Embedded underwater front-end electronics for the 3-inch photomultipliers in the JUNO experiment

TL;DR

This paper details the design, implementation, and validation of underwater front-end electronics for 3-inch photomultiplier tubes in the JUNO neutrino detector, ensuring high sensitivity and reliable operation.

Contribution

It introduces a novel integrated electronics system for small PMTs in JUNO, with comprehensive validation demonstrating readiness for physics measurements.

Findings

Achieved noise levels as low as 0.04 photoelectrons.

System bandwidth of 57 MB/s supports high-rate data acquisition.

Full system integration and validation confirm operational readiness.

Abstract

The Jiangmen Underground Neutrino Observatory (JUNO) is a 20-kton liquid scintillator-based, low-radioactivity, multi-purpose neutrino detector located 693 meters (1800 m.w.e.) underground in the Guangdong province, China. To detect scintillation light produced in the target, the detector is equipped with 17,612 20-inch photomultipliers (PMTs), forming the Large PMT system (LPMT). In addition, 25,600 3-inch photomultipliers (the Small Photomultiplier System or SPMT) are deployed in the gaps between the LPMTs. This paper presents the design and performance of the underwater front-end electronics developed for the SPMT system. It details the individual electronics boards and their key components, the inter-board interfaces, the system-level design, and the firmware architecture that supports data acquisition and control. It also outlines mechanical and thermal integration, board validation procedures, and system performance metrics. The readout chain includes digitization of 128 PMT channels per unit, synchronized time-stamping, charge measurement, event packaging, and bandwidth management. Comprehensive validation confirms the system's readiness to meet JUNO's stringent physics goals. The underwater electronics achieve noise levels as low as 0.04 photoelectrons with minimal crosstalk (below 0.4%) and a bandwidth of 57 MB/s, ensuring reliable single photo-electron detection and operation under high-rate conditions. The SPMT system has now been fully integrated and installed in JUNO. Its commissioning and physics performance will be reported in a future publication.