IBM Collaborates with University of Sherbrooke to Launch Two New Quantum Research Chairs Focused on Algorithm Discovery

IBM and the University of Sherbrooke have established two quantum research chairs focused on advancing algorithm development for noise-robust and fault-tolerant quantum computing. The initiative aims to enhance practical applications in areas such as materials science and multi-body quantum systems. It seeks to recruit students with strong backgrounds in physics, computer science, or mathematics to contribute to these cutting-edge projects.

Quantum Computing Research Chair at UdeS

The new quantum computing research chair at UdeS focuses on advancing algorithm development to maximize the potential of emerging quantum systems. The primary goal is to create noise-robust quantum utility algorithms and early fault-tolerant quantum algorithms, with students playing a central role in every stage of the research process. This includes idea generation, literature review, project meetings, mathematical modelling, simulations, implementation, and publication of results. Applications of this work are expected to impact quantum computing itself, scientific research, and long-term advancements in materials science.

Students interested in joining the projects should have strong physics, computer science, or mathematics backgrounds, with desirable skills including algorithm design, computational theory, numerical methods, quantum physics, and programming expertise. The initiative’s success will be measured by students’ professional growth, contributions to scientific knowledge, and progress in developing high-impact technologies.

Advancements and Changes in Quantum Computing Since Its Inception

The new quantum computing research chair at UdeS aims to advance algorithm development to fully exploit emerging quantum systems. Key objectives include creating noise-robust quantum utility algorithms and early fault-tolerant quantum algorithms. Students play a central role in every stage of the research process, including idea generation, literature review, project meetings, mathematical modeling, simulations, implementation, and publication of results.

The applications of this work are expected to enhance quantum computing capabilities, contribute to scientific research, particularly in studying multi-body quantum systems, and drive long-term advancements in materials science. Students interested in joining the projects should have strong backgrounds in physics, computer science, or mathematics, along with skills in algorithm design, computational theory, numerical methods, quantum physics, and programming expertise.

Success will be measured by students’ professional growth, contributions to scientific knowledge, and progress in developing impactful technologies. The initiative emphasizes interdisciplinary collaboration and aims to produce high-quality research while fostering the next generation of quantum computing talent.

Student Training and Future Success Metrics

The new quantum computing research chair at UdeS is focused on advancing algorithm development to fully leverage emerging quantum systems. The initiative prioritizes creating noise-robust quantum utility algorithms and early fault-tolerant quantum algorithms, with students playing a central role in all stages of research. This involves generating ideas, conducting literature reviews, holding project meetings, developing mathematical models, performing simulations, implementing solutions, and publishing findings.

The applications of this work are expected to enhance quantum computing capabilities, contribute to scientific research, particularly in studying multi-body quantum systems, and drive long-term advancements in materials science. Students interested in joining the projects should have strong backgrounds in physics, computer science, or mathematics, along with skills in algorithm design, computational theory, numerical methods, quantum physics, and programming expertise.

Success will be measured by students’ professional growth, contributions to scientific knowledge, and progress in developing impactful technologies. The initiative emphasizes interdisciplinary collaboration and aims to produce high-quality research while fostering the next generation of quantum computing talent.