Origin and characterization of single-electron events in Skipper-CCDs for light dark matter searches

TL;DR

This paper details the development and characterization of Skipper-CCDs for light dark matter detection, highlighting improved event selection, background reduction, and the most stringent limits to date on certain dark matter interactions.

Contribution

It introduces new methods for event selection and background suppression in Skipper-CCDs, leading to record low dark current and spurious charge levels, enhancing dark matter search sensitivity.

Findings

Achieved the lowest dark current and spurious charge levels in CCDs.

Set the most stringent limits on light dark matter interactions to date.

Optimized detector operation parameters for improved sensitivity.

Abstract

This manuscript summarizes the work carried out within the SENSEI (Sub-Electron-Noise Skipper-CCD Experimental Instrument) collaboration, an effort focused on the search for light dark matter using Skipper-CCDs. Firstly, it presents the data acquisition and processing protocol developed to establish a selection criteria for events compatible with the dark matter signal. This protocol also enabled the structure and tools used for the study and characterization of phenomena that impact the quality of measurements made in the search for dark matter (measurement of the Fano factor, determination of the Compton background, and characterization of the high-energy surface background), which were carried out during this work. Secondly, it discusses the comprehensive study conducted on the origin of single-electron events in Skipper-CCDs, which allowed for the selection of detector operating parameters and improved the detection sensitivity in the search for dark matter. It is highlighted the characterization of the spatial correlation between single-electron events and high-energy events, among other developed event selection criteria, and the optimization of the output device to reduce sources of luminescence during its operation. As a result of this study, the lowest levels of dark current and spurious charge ever measured in a CCD are reported. Finally, the latest published results from SENSEI are presented. The obtained limits for the scattering of a light mediator are the best reported to date across the entire investigated mass range, while for the heavy mediator, they are the best for masses below 10 MeV. In terms of dark matter absorption, the most restringent limits below 10 eV are reported. These results, achieved with only a very small fraction of the total projected exposure for SENSEI, position Skipper-CCDs as leaders in the search for light dark matter worldwide.