Candidate: Michael Mazurek
Title: Testing classical and quantum theory with single photons
Silicon metal-oxide-semiconductor field effect transistor (MOSFET) quantum dots are promising candidates for scalable quantum computing using electron spin qubits due to their long coherence times, compact size, and ease of integration into existing fabrication technologies. I will introduce how we fabricate these devices and describe the experimental characterizations we do to check the stability and tunability of our quantum dots. In a double quantum dot device, two qubit gates are realized
Thursday, December 21, 2017 (Ottawa, Ontario) – An exhibition on quantum technologies from the University of Waterloo’s Institute for Quantum Computing (IQC) is captivating curious minds at the newly reopened Canada Science and Technology Museum.
CryptoWorks21 at the University of Waterloo, together with representatives from the Standards Council of Canada (SCC) and the European Telecommunications Standards Institute (ETSI), are proud to present a lunch-time standards session.
“He who is good with a hammer thinks everything is a nail.”
- Modified quote from the original by Abraham Maslow
How does one sell security? How does one commercialize such nebulous concepts such as “Trust”, “Security” and “Cryptography”? Cryptography, which is just one building block of security, is based on other more abstract building blocks such as algorithms which have a foundation on hard mathematical problems.
I will introduce quantum annealing as a technique for harnessing quantum mechanics to solve hard problems. The design of a quantum annealing processor based on superconducting flux qubits, some of the challenges we have encountered in constructing it, and measurements confirming the role of quantum mechanics in such processors will be presented. Finally, I will briefly discuss recent benchmarking and simulation results using the D-Wave 2000Q processor.
Quantum information processing (QIP) has been identified as one of the key future technologies that are crucial for communication, cryptography, computing, complex-system simulation, metrology, artificial intelligence and national security. Quantum control, on the other hand, provides a powerful tool to analyze and improve the physical performances of different QIP devices.
Transformative Quantum Technologies (TQT) invites the University of Waterloo community to explore the Research Advancement Centre 2 (RAC 2) building and see first-hand where groundbreaking research in quantum information and science technology happens.
Semiconductor electron pump devices have shown promise for current standards due to their high accuracy current transport [1]. Further to this, at higher fields and frequencies these pumps demonstrate excitation states corresponding to energies in the microwave range [2]. This suggests possible applications in microwave and THz photonics, an emerging field with applications spanning from quantum information processing to medical imaging.