"Beyond Binary Quantum Information...", Machiel Blok скачать в хорошем качестве

"Beyond Binary Quantum Information...", Machiel Blok

Beyond Binary Quantum Information: Controlling the Excited States of “Artificial Atoms” in Superconducting Circuits Abstract: Encoding quantum information in the higher energy levels of the transmon circuit provides a resource efficient way to control large Hilbert spaces and to execute quantum algorithms at reduced circuit complexity. Building on recent demonstrations of the first qu-trit quantum processor at UC Berkeley [1,2], here I will discuss ongoing work in our lab at the University of Rochester to explore the transmon spectrum. We demonstrate preparation and readout of Fock states of up to ten microwave photons. Furthermore, we illustrate how the strong Kerr non-linearity of the transmon allows us to implement non-Gaussian operations that are challenging to realize in a linear mode. In the long term, we anticipate this new approach to controlling higher-level quantum information to yield benefits for bosonic quantum error correction and qu-dit simulation. [1] Quantum Information Scrambling in a Superconducting Qutrit Processor M. S. Blok et al PRX 11, (2) 021010 (2021) [2] Qutrit Randomized Benchmarking A. Morvan et al PRL 126 (21), 210504 (2021) Bio: Machiel Blok received his PhD in physics from Delft University of Technology/QuTech (The Netherlands) where he worked with Prof. Ronald Hanson on defect centers in diamond with a focus on quantum measurement, real-time feedback and remote entanglement. During his postdoc at UC Berkeley, in the group of Prof. Irfan Siddiqi, he developed a qutrit quantum processor in superconducting circuits. In 2020 he joined the faculty of Physics and Astronomy Department of University of Rochester as an Assistant professor, where he started a superconducting circuits lab as the inaugural Levinson/Shapiro Faculty Scholar.