Characterization of Pulse–Shape Discrimination for Background Reduction in the DEAP-1 Detector

Pasuthip, PARADORN

02 February 2009

DEAP (Dark Matter Experiment with Argon and Pulse Shape Discrimination) is an experiment that aims to directly detect dark matter particles via nuclear recoils in liquid argon. The experiment uses the scintillation property of liquid argon as a means to discriminate the γ and β backgrounds from the expected signal. DEAP-1 is a 7 kg single phase liquid argon detector. It was constructed to demonstrate the scalability for a larger (3600 kg) detector. The detector was originally operated at Queen’s University, where the background rejection level achieved was 6.3×10−8 for the recoil detection efficiency of 97.1%. The detector was relocated to SNOLAB, where the background in the energy region of interest was reduced by a factor of 7.7 (from 4.61±0.17 mHz to 0.60±0.05 mHz.). The background rejection level of 9.64×10−9 (10.4 part per billion) was achieved from the combined data set (Queen’s University and SNOLAB) for a recoil detection efficiency of 35.5 ± 1.3 %. With the current background rate, the background rejection level required for the 3600 kg detector (1.8×10−9 ) is projected to be achieved in 382 days at the neutron efficiency of 9.1±0.6 %. / Thesis (Master, Physics, Engineering Physics and Astronomy) -- Queen's University, 2009-01-26 09:28:25.432

Dark Matter

Argon detector

The Influence of Sputtering Pressure and Film Thickness on Metal Resistivity

Xu, Can

Unknown Date

No description available.

Sputtering

Argon Pressure

Resistivity

Investigation of argon plasma properties at high pressure

Wynn, Marvin Craig

08 1900

No description available.

Argon

Electric conductivity

Non-condensable gas dynamics in the heat pipe

Zevallos, Gonzalo Efrain

08 1900

No description available.

Heat Transmission

Argon

Energy resolution of a liquid argon electromagnetic calorimeter with pointing accordion geometry

Robertson, Steven Hugh

10 November 2011

Graduate

liquid argon

calorimeters

A low noise lifetime measurement of electrons drifting in liquid argon

Bishop, Shawn

22 November 2011

Graduate

liquid argon

cryostat

Dielectric constants of simple gases determined using microwave cavity resonators

Royal, Damian Derek

January 2000

No description available.

541

Argon; Xenon; Non-polar

Fundamental properties of a microwave induced argon plasma

Surrey, E.

January 1987

No description available.

530.44

Argon plasma properties

The Influence of Sputtering Pressure and Film Thickness on Metal Resistivity

Xu, Can

06 1900

Electrical resistivity is an important indicator of metal thin film quality. In this study, the influence of argon working pressure on the properties of metal thin films was evaluated, and the thickness effect on the resistivity of metal thin films was investigated. The sputtered thin film resistivity performances of seven metals as a function of argon pressure were measured, and the results turned out that the argon pressure was vital to film quality. Further investigation on sputtered chromium thin films using XRD, SEM and XPS revealed that the argon pressure influences the microstructure of sputtered metal thin films. Different microstructure is the reason for different resistivity performances, and John Thornton's "Zone Model" explains all these behaviours well. The resistivity of aluminum and chromium thin films with thickness from 15 to 150 nm were compared, the resistivity change significantly. The scaling trends are different for different metals. / Materials Engineering

Sputtering

Argon Pressure

Resistivity

An investigation of a new method for potassiumargon age determination

Barnes, Ira Lynus

January 1963

Typescript. / Thesis (Ph. D.)--University of Hawaii, 1963. / Bibliography: leaves 107-113. / viii, 114 l illus., diagrs., tables

Potassium-argon dating