Following on the success of the Sudbury Neutrino Observatory (SNO), culminating with the award of the 2015 Nobel Prize in Physics, the SNO underground laboratory has been expanded to the new SNOLAB facility which includes new experimental halls and infrastructure. SNOLAB is designed to house a variety of experiments that will investigate the properties of the fundamental constituents of the universe including neutrinos and dark matter.
More information about SNOLAB is available at: http://www.snolab.ca
The SNOLAB group at Carleton has research positions available associated with the nEXO and DEAP collaborations. Also, students graduating with a B.Sc. Physics are encouraged to apply for graduate studies in our group to start in September.
nEXO collaboration: Search for neutrinoless double beta decay
The nEXO collaboration is developing detector techniques that will facilitate a precision search for the rare process known as neutrinoless double beta decay. A definitive discovery of this process would provide new information on the properties of neutrinos. The design of nEXO, large enriched-xenon detector, is under development towards installation at SNOLAB.
The Carleton group focuses on testing ultraviolet-sensitive silicon photomultipliers (SiPM) directly in liquid xenon at cryogenic temperature.
nEXO contacts:
Professor Razvan Gornea, Department of Physics, Carleton University
Professor Simon Viel, Department of Physics, Carleton University
DEAP collaboration: Search for dark matter with DEAP-3600
The DEAP collaboration has installed DEAP-3600, a large liquid argon detector at SNOLAB to search directly for dark matter. The experiment is currently taking data, and is presently the most sensitive liquid argon detector in operation. The detector utilizes scintillation signals produced in the argon, wavelength-shifted using a layer of tetraphenyl butadiene (TPB) and detected with an array of photomultiplier tubes (PMT). Current efforts at Carleton focus on detector operation and data analysis.
Undergraduate student research projects are offered on data analysis and detector Monte Carlo simulations using C++ and Python, with the goal of calibrating the detector, understanding the types of events observed, and improving the sensitivity of the dark matter search. Students will also contribute to DEAP-3600 operations with shifts for the monitoring and maintenance of the detector.
DEAP-3600 contacts:
Professor Mark Boulay, Department of Physics, Carleton University
Professor Simon Viel, Department of Physics, Carleton University
DEAP collaboration: Research and development towards future dark matter detectors
Members of the DEAP collaboration have also joined the Global Argon Dark Matter Collaboration, working towards the construction of larger, more sensitive liquid argon detectors to search for dark matter. The first such detector, DarkSide-20k, is scheduled for installation at Gran Sasso National Laboratory (Italy), with a target mass above 20 tonnes. Then the community plans to build a 400-tonnes liquid argon detector, with ultimate world-leading sensitivity to weakly interacting massive particles.
Students on this project will work on the following activities:
- Research and development of silicon photomultiplier (SiPM) devices operating at cryogenic temperature with ability to detect scintillation light from liquid argon
- Design studies using Monte Carlo simulations, to maximise the sensitivity of future liquid argon experiments to observe dark matter
DEAP future liquid argon detector contacts:
Professor Mark Boulay, Department of Physics, Carleton University
Professor Simon Viel, Department of Physics, Carleton University