On January 21, the Natural Sciences and Engineering Research Council of Canada (NSERC) announced funding for quantum science projects, including six initiatives at uOttawa. These awards reinforce the University’s commitment to exploring quantum science and driving innovation in Canada.

Over $4 million in Federal investment will allow researchers from the UBC Stewart Blusson Quantum Matter Institute to form collaborations in quantum materials and computing, advancing innovative technologies such as quantum light sources for applications in computing, sensing, and communications.

On the occasion of the extension of the program, a signing ceremony took place on January 20, 2025. Prof. Benoit-Antoine Bacon, President of UBC, Prof. Peter Middendorf, Rector of the University of Stuttgart, and Prof. Bernhard Keimer, Director of the MPI-FKF, attended the event.

A team of researchers from the University of Ottawa has developed innovative methods to enhance frequency conversion of terahertz (THz) waves in graphene-based structures, unlocking new potential for faster, more efficient technologies in wireless communication and signal processing.

Canada has announced over CA$74 million (approximately $52 million) in funding for 107 quantum science projects, in order to advance quantum technologies in areas like quantum computing, communications, encryption, materials, and sensing. The funding aligns with Canada’s National Quantum Strategy and includes partnerships with private, public, and international organizations.

A team of physicists led by The City College of New York’s Lia Krusin-Elbaum has developed a novel technique that uses hydrogen cations (H+) to manipulate relativistic electronic bandstructures in a magnetic Weyl semimetal -- a topological material where electrons mimic massless particles called Weyl fermions. These particles are distinguished by their chirality or “handedness” linked to their spin and momentum.

Currently, the most efficient way to create photon pairs requires sending lightwaves through a crystal large enough to see without a microscope. In a paper published today in Nature Photonics, a team led by Columbia Engineering researchers and collaborators, describe a new method for creating these photon pairs that achieves higher performance on a much smaller device using less energy. P. James Schuck, associate professor of mechanical engineering at Columbia Engineering, helped lead the research team.

In a new study, researchers from the MCQST, the Max Planck Institute of Quantum Optics and the LMU under the lead of Timon Hilker demonstrated evidence of stripe formation, i.e. extended structures in the density pattern, in a cold-atom Fermi-Hubbard system. By using a quantum gas microscope and a special mixed-dimensional geometry, they were able to observe unique higher-order correlations in spin and charge densities related to those seen in some high-temperature superconducting materials.

In a cold-atom Fermi Hubbard model, researchers observed extended and attractive correlations between hole dopants and indications of stripes that are associated with superconductivity, opening up novel insights into the behaviour of exotic quantum phases.

Researchers from the National University of Singapore (NUS) have recently achieved a significant breakthrough in the development of next-generation carbon-based quantum materials, opening new horizons for advancements in quantum electronics.