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Skip to Search Results- 1Bina, Catherine E.
- 1Farahani, Sina Safarabadi
- 1McElroy, Thomas J.
- 1Mielnichuk, Courtney T.
- 1Olsen, Kevin Sutherland
- 1Sibley, Logan AB
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A LIKELIHOOD RATIO ALGORITHM FOR REMOVING LOCALIZED ALPHA PARTICLE BACKGROUNDS IN THE DEAP-3600 DETECTOR
DownloadSpring 2017
DEAP-3600 (Dark Matter Experiment using Argon for Pulse shape discrimination) is a single phase dark matter experiment using a tonne-scale mass of liquid argon as a target to observe spin-independent interactions with Weakly Interacting Massive Particles (WIMPs). Alpha decays from radioactive...
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Fall 2023
This thesis provides an investigation of various aspects of the major background in the SNO+ experiment and its associated detector. The initial chapters present an overview of neutrino physics and the SNO+ detector, providing relevant background information. The impact of light reflection on the...
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A Search for Dark Matter Interactions in the DEAP 3600 Detector Using Fiducial Masses Ranging from 1433 to 2966 kg
DownloadFall 2023
The DEAP-3600 detector is a single-phase direct-detection Dark Matter (DM) experiment located 2 km underground at SNOLAB in Sudbury, Canada. The detector consists of 3279 kg of liquid Argon contained in a spherical acrylic vessel. DEAP-3600 was specifically designed to search for direct detection...
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Spring 2019
Identification of, and discrimination against, background radiation is of the utmost importance in dark matter searches. DEAP-3600 (Dark Matter Experiment using Argon Pulse shape discrimination) is a single phase, direct dark matter detector with a 3300 kg liquid argon target housed in a...
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Fall 2018
Dark Matter is a fundamental building block and is essential for the universe to be understood on many scales. Currently, the top candidate for Dark Matter is a weakly interacting massive particle (WIMP). The DEAP-3600 experiment was built to search for rare interactions between baryonic matter...
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Improvements to the resolution and efficiency of the DEAP-3600 dark matter detector and their effects on background studies
DownloadFall 2010
The Dark matter Experiment using Argon Pulse-shape discrimination will be a tonne scale liquid argon experiment to detect scintillation light produced by interactions with weakly interacting massive particles, leading dark matter candidates. The detector will be constructed out of acrylic and use...
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The SNO+ liquid scintillator response to low-energy electrons and its effect on the experiment’s sensitivity to a future neutrinoless double beta decay signal
DownloadFall 2016
The SNO+ experiment is set to join the international competition of experiments searching for neutrinoless double beta decay. By loading 780 t of liquid scintillator with 0.5% natural tellurium, and with its location 2 km underground at SNOLAB, SNO+ aims to have sensitivity to determining the...