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at the University of Waterloo and the Institute for Quantum Computing. Dedicated research facilities include state-of-the-art faculties for materials growth and characterization, a wide range of low
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. The application themes deal with major societal issues, such as carbon neutrality, raw material scarcity, circular economy, etc. Mechanical Engineering The candidate will be expected to contribute to the Mechanical
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, Advisory Group and other stakeholders and organize regular meetings webinars, retreat(s), and engagement events; Assist with developing survey/interviews and recruitment materials; Undertake primary and
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, Advisory Group and other stakeholders and organize regular meetings webinars, retreat(s), and engagement events; Assist with developing survey/interviews and recruitment materials; Undertake primary and
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condensed matter physics and neutron scattering Relevant Fields: Phase transitions, topological materials, neutron optics, matter wave interferometry Required skills: Hands-on experience with low temperature
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physics and quantum optics Relevant Fields: Phase transitions, topological materials, quantum optics Required Skills: Hands-on experience with optic and quantum optics elements, handling brittle and
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contribute to the collaborative TQT research community. Principal Investigator: Na Young Kim Project: Carbon Nanotube (CNT) Quantum Electronic Devices Research Area: CNT material growth/processing and device
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help to realize them experimentally on our quantum simulator. We are especially interested in simulating quantum many-body models relevant to materials science and condensed matter physics. We are also
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devices. The project will rely on UHV and MBE growth. It will connect both materials and device characteristics to improved growth methods. Experience with the following is useful: UHV methods MBE XRD LT
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September 2019 to accelerate the development of novel quantum materials by harnessing the power of quantum simulators. Our first-generation quantum simulation exploits configurations of neutral atoms