6533b822fe1ef96bd127cbfd
RESEARCH PRODUCT
Efficient protocol for qubit initialization with a tunable environment
Jani TuorilaJani TuorilaMatti PartanenTapio Ala-nissilaTapio Ala-nissilaTapio Ala-nissilaMikko MöttönenMikko Möttönensubject
Flux qubitComputer Networks and CommunicationsQC1-999FOS: Physical sciencesInitialization02 engineering and technologyQuantum channelCOMPUTATIONTopology01 natural sciencesPhase qubitComputer Science::Emerging TechnologiesSuperdense codingQuantum mechanicsMesoscale and Nanoscale Physics (cond-mat.mes-hall)0103 physical sciencesComputer Science (miscellaneous)010306 general physicsDISSIPATIONPhysicsQuantum PhysicsSUPERCONDUCTING QUANTUM BITSERROR-CORRECTIONCondensed Matter - Mesoscale and Nanoscale PhysicsPhysicskvanttitietokoneetCIRCUITAMPLIFICATIONStatistical and Nonlinear PhysicsOne-way quantum computerQuantum PhysicsQA75.5-76.95021001 nanoscience & nanotechnologyqubit initializationSTATETRAPPED IONSComputational Theory and MathematicsQubitElectronic computers. Computer sciencequbitsQuantum Physics (quant-ph)0210 nano-technologyQuantum teleportationdescription
We propose an efficient qubit initialization protocol based on a dissipative environment that can be dynamically adjusted. Here the qubit is coupled to a thermal bath through a tunable harmonic oscillator. On-demand initialization is achieved by sweeping the oscillator rapidly into resonance with the qubit. This resonant coupling with the engineered environment induces fast relaxation to the ground state of the system, and a consecutive rapid sweep back to off resonance guarantees weak excess dissipation during quantum computations. We solve the corresponding quantum dynamics using a Markovian master equation for the reduced density operator of the qubit-bath system. This allows us to optimize the parameters and the initialization protocol for the qubit. Our analytical calculations show that the ground-state occupation of our system is well protected during the fast sweeps of the environmental coupling and, consequently, we obtain an estimate for the duration of our protocol by solving the transition rates between the low-energy eigenstates with the Jacobian diagonalization method. Our results suggest that the current experimental state of the art for the initialization speed of superconducting qubits at a given fidelity can be considerably improved.
| year | journal | country | edition | language |
|---|---|---|---|---|
| 2017-07-14 | npj Quantum Information |