Gas Gains Over 10$^4$ and Optimisation using $^{55}$Fe X-rays in Low Pressure SF$_6$ with a Novel Multi-Mesh ThGEM for Directional Dark Matter Searches

TL;DR

This paper introduces a novel Multi-Mesh ThGEM structure that significantly enhances gas gain in SF$_6$, a Negative Ion Drift gas, achieving gains up to 90,000, thereby improving the sensitivity of directional dark matter detectors.

Contribution

The paper presents a new Multi-Mesh ThGEM design that achieves an order of magnitude higher gas gain in SF$_6$ compared to previous methods, enabling better dark matter detection.

Findings

Achieved stable gas gains up to ~90,000 in SF$_6$.

Optimized device by varying field strengths for maximum gain.

Demonstrated significant improvement over previous gas gain limits.

Abstract

The Negative Ion Drift (NID) gas SF$_6$ has favourable properties for track reconstruction in directional Dark Matter (DM) searches utilising low pressure gaseous Time Projection Chambers (TPCs). However, the electronegative nature of the gas means that it is more difficult to achieve significant gas gains with regular Thick Gaseous Electron Multipliers (ThGEMs). Typically, the maximum attainable gas gain in SF$_6$ and other Negative Ion (NI) gas mixtures, previously achieved with an $^{55}$Fe X-ray source or electron beam, is on the order of $10^3$; whereas electron drift gases like CF$_4$ and similar mixtures are readily capable of reaching gas gains on the order of $10^4$ or greater. In this paper, a novel two stage Multi-Mesh ThGEM (MMThGEM) structure is presented. The MMThGEM was used to amplify charge liberated by an $^{55}$Fe X-ray source in 40 Torr of SF$_6$. By expanding on previously demonstrated results, the device was pushed to its sparking limit and stable gas gains up to $\sim$50000 were observed. The device was further optimised by varying the field strengths of both the collection and transfer regions in isolation. Following this optimisation procedure, the device was able to produce a maximum stable gas gain of $\sim$90000. These results demonstrate an order of magnitude improvement in gain with the NID gas over previously reported values and ultimately benefits the sensitivity of a NITPC to low energy recoils in the context of a directional DM search.