Quantum Technology
Enhancing Quantum Computer Readout
Using a variety of simulation techniques, our researchers are modeling superconducting qubit noise to predict the readout noise, optimize the pulse width, energy, and resonator design for high-fidelity readout. Below is a rotating selection of our standout investigators in this subject matter.
○ Recent News and Highlights
○ Related Strength: Semiconductors
Featured Faculty
Curtis Asplund
Assistant Professor of Physics and Astronomy
High Energy Theoretical Physics, Entanglement Entropy and Complexity of Quantum Field
Theories and Black Holes, Applications of Gauge/Gravity Duality to Condensed Matter
Systems
ORCID: 0000-0003-0557-5850
Kassahun Betre
Assistant Professor of Physics and Astronomy
High-Energy Theory, Quantum Gravity, Theoretical Particle Physics
ORCID: 0000-0003-1063-5870
Hilary M Hurst
Assistant Professor of Physics and Astronomy
Quantum Physics, Quantum Control, Quantum Information Science, Ultracold Gases, Bose-Einstein
Condensation, Spinor Condensate, Weak Measurement, Quantum Measurement
ORCID: 0000-0002-7197-7615
Ehsan Khatami
Professor of Physics and Astronomy
Quantum Many-Body Physics, Quantum simulations, Condensed Matter Physics, Numerical
Methods, Machine Learning
ORCID: 0000-0003-4256-6232
Hiu-Yung Wong
Associate Professor of Electrical Engineering
Quantum Computing Device and Algorithm, TCAD Simulation, Semiconductor, Wide-Bandgap
Device, Machine Learning, Device Physics, Neuromorphic Computing
ORCID: 0000-0003-0135-7469
Potential collaborators and members of the media may contact us at officeofresearch@mblayst.com.