Environmental radon control in the 700-m underground laboratory at JUNO

TL;DR

This paper discusses the strategies and results of controlling radon levels in the world's largest underground neutrino detector at JUNO, emphasizing ventilation optimization and source identification.

Contribution

It presents the first comprehensive radon control approach in a large underground laboratory, including source analysis and effective ventilation strategies.

Findings

Radon levels in the main hall reduced from 1600 Bq/m³ to 100 Bq/m³.

Underground water identified as a major radon source.

Optimized ventilation effectively controls radon concentration.

Abstract

The Jiangmen Underground Neutrino Observatory is building the world's largest liquid scintillator detector with a 20 kt target mass and about 700 m overburden. The total underground space of civil construction is about 300,000 m$^3$ with the main hall volume of about 120,000 m$^3$, which is the biggest laboratory in the world. Radon concentration in the underground air is quite important for not only human beings' health but also the background of experiments with rare decay detection, such as neutrino and dark matter experiments. The radon concentration is the main hall is required to be around 100 Bq/m$^3$. Optimization of the ventilation with fresh air is effective to control the radon underground. To find the radon sources in the underground laboratory, we made a benchmark experiment in the refuge room near the main hall. The result shows that the radon emanating from underground water is one of the main radon sources in the underground air. The total underground ventilation rate is about 160,000 m$^3$/h fresh air with about 30 Bq/m$^3$ $^{222}$Rn from the bottom of the vertical tunnel after optimization, and 55,000 m$^3$/h is used for the ventilation in the main hall. Finally, the radon concentration inside the main hall decreased from 1600 Bq/m$^3$ to around 100 Bq/m$^3$. The suggested strategies for controlling radon concentration in the underground air are described in this paper.