An ultra-light helium cooled pixel detector for the Mu3e experiment

TL;DR

This paper demonstrates a novel ultra-light pixel detector cooled with gaseous helium, enabling high-performance tracking for the Mu3e experiment with minimal material and innovative cooling techniques.

Contribution

It introduces the first successful cooling of a pixel tracker using gaseous helium and integrates HV-MAPS sensors with this cooling method for the Mu3e experiment.

Findings

Gaseous helium cooling keeps the detector below 70°C at high heat densities.

HV-MAPS sensors operate effectively with helium cooling.

The approach achieves a material budget of approximately 0.1% X/X0.

Abstract

The Mu3e experiment searches for the lepton flavour violating decay $\mu^+ \rightarrow e^+ e^- e^+$ with an ultimate aimed sensitivity of $1$ event in $10^{16}$ decays. To achieve this goal, the experiment must minimize the material budget per tracking layer to $X/X_0\approx 0.1\,\%$ and use gaseous helium as coolant. The pixel detector uses High-Voltage Monolithic Active Pixel Sensors (HV-MAPS) which are thinned down to $50\, \mu m$. Both helium cooling and HV-MAPS are a novelty for particle detectors. Here, the work on successfully cooling a pixel tracker using gaseous helium is presented. The thermal studies focus on the two inner tracking layers, the Mu3e vertex detector, and the first operation of a functional thin pixel detector cooled with gaseous helium. The approach, which circulates gaseous helium under ambient pressure conditions with a gas temperature around $0\,{\deg}C$ using a miniature turbo compressor with a mass flow of $2\,g/s$ allows the vertex detector to operate below $70\,{\deg}C$ at heat densities of up to $350\,mW/cm^2$. Finally, performance data of the final HV-MAPS used by Mu3e, the MuPix11, is presented. These results demonstrate the feasibility of using HV-MAPS combined with gaseous helium as a coolant for an ultra-thin pixel detector exploring new frontiers in lepton flavor.