IQC Student Seminar featuring Lane Gunderman
Changing the local-dimension of an entanglement-assisted stabilizer code removes entanglement need
Changing the local-dimension of an entanglement-assisted stabilizer code removes entanglement need
Designing control protocols to enhance the coherence of superconducting qubits
Speaker: Ziwen Huang, Northwestern University
Precision Measurements with 31P Nuclear Spins in Isotopically Enriched 28Si
Join us February 12 at 7pm EST for a virtual screening event featuring the ten finalists of the Quantum Shorts festival.
The quantum sign problem: perspectives from computational physics and quantum computer science
Dominik Hangleiter, FreieUniversität Berlin
Join us for casual conversations with quantum researchers.
What makes a superconducting qubit tick? How does experience in a research lab prepare you for working on major projects after graduation?
We’ll talk about these topics and more with IQC alumnus Thomas McConkey, now a Microwave Design Engineer at IBM Q, at the next virtual fireside chat.
FemPhys and the Institute for Quantum Computing (IQC) are hosting an online mentoring event for undergraduate and graduate students at the University of Waterloo. Mentors, all women or of minoritized identities with backgrounds in STEM, will share their experiences and inspire the upcoming generations of scientists and people in STEM.
Join us for casual conversations with quantum researchers.
Twesh Upadhyaya, IQC graduate student, joins us for a virtual Fireside Chat to talk about finding a passion for quantum information science in high school and to share his journey to studying the theory of quantum security.
Computability and compression of nonlocal games
Sajjad Nezhadi, University of Maryland - College Park
Quantum information science promises great potential to revolutionize our current technologies such as quantum computation, which can solve classically inaccessible problems. To build a practical quantum computer, it is essential to have precise control over individual quanta. By interfacing free-space photons and atomic platforms, we can maximize the performance of quantum computation, as each platform has its own advantages.