Optimal operating parameters for next-generation xenon gas time projection chambers

TL;DR

This paper analyzes how design choices in next-generation gaseous xenon TPC detectors affect their ability to detect neutrinoless double beta decay, emphasizing background reduction and optimal operating conditions.

Contribution

It provides a comprehensive evaluation of design parameters and gas technologies for xenon TPCs, identifying optimal configurations for next-generation experiments.

Findings

Enriched xenon TPCs have significantly lower background rates than natural xenon.

Optimal performance is achieved with detector pressures between 5 and 25 bars.

Background levels below 0.2 events per tonne-year are feasible with suitable technology.

Abstract

The next-generation of $0\nu\beta\beta$ searches are targeting half-life sensitivities towards 10$^{27}$--10$^{28}$ years. Gaseous xenon time projection chamber (GXeTPC) detectors may be able to meet this challenge due to their excellent energy resolution and background rejection power through event visualization. This paper explores how the design choices of a next-generation GXeTPC time projection chamber can impact the overall performance of the experiment. We study the performance of systems using xenon enriched in the isotope $^{136}$Xe or natural xenon, focusing on scenarios that incorporate one tonne of $^{136}$Xe isotope. The detector size, copper shielding mass, energy resolution, density and corresponding levels of diffusion are surveyed to evaluate the overall performance dependencies on these parameters. A detector optimized for using enriched xenon is preferred over natural, due primarily to a factor of 10 lower background rate driven by the large intrinsic backgrounds introduced by the copper shielding used in the detector. The performance of three types of gas TPC technologies was also explored based on different gas additives used to reduce diffusion to different levels. For all TPC technologies, we find background rates of a fraction of a count per tonne year in the region of interest are achievable. These performance levels are contingent on suitable energy resolution and event position placement in the drift direction being achieved for the specific detector technology. Performance for enriched xenon TPCs varies mildly with pressure in the range 5 to 25 bars, reaching background levels below 0.2 events/tonne-year. Performance at one bar is worse by approximately a factor of four. When considerations for the construction of the detector in addition to the selection performance are included, there may be no clearly optimum pressure.