no code implementations • 25 Feb 2021 • J. F. Marques, B. M. Varbanov, M. S. Moreira, H. Ali, N. Muthusubramanian, C. Zachariadis, F. Battistel, M. Beekman, N. Haider, W. Vlothuizen, A. Bruno, B. M. Terhal, L. DiCarlo
We realize a suite of logical operations on a distance-two logical qubit stabilized using repeated error detection cycles.
Quantum Physics Superconductivity
no code implementations • 7 Dec 2020 • R. Sagastizabal, S. P. Premaratne, B. A. Klaver, M. A. Rol, V. Negîrneac, M. Moreira, X. Zou, S. Johri, N. Muthusubramanian, M. Beekman, C. Zachariadis, V. P. Ostroukh, N. Haider, A. Bruno, A. Y. Matsuura, L. DiCarlo
The preparation of thermal equilibrium states is important for the simulation of condensed-matter and cosmology systems using a quantum computer.
Quantum Physics
no code implementations • 22 Sep 2011 • M. D. Reed, L. DiCarlo, S. E. Nigg, L. Sun, L. Frunzio, S. M. Girvin, R. J. Schoelkopf
The simplest of these are the three-qubit codes, which map a one-qubit state to an entangled three-qubit state and can correct any single phase-flip or bit-flip error of one of the three qubits, depending on the code used [2].
Quantum Physics Mesoscale and Nanoscale Physics Superconductivity
no code implementations • 11 Mar 2009 • L. DiCarlo, J. M. Chow, J. M. Gambetta, Lev S. Bishop, B. R. Johnson, D. I. Schuster, J. Majer, A. Blais, L. Frunzio, S. M. Girvin, R. J. Schoelkopf
By harnessing the superposition and entanglement of physical states, quantum computers could outperform their classical counterparts in solving problems of technological impact, such as factoring large numbers and searching databases.
Mesoscale and Nanoscale Physics Quantum Physics