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RESEARCH PRODUCT
Rovibrational controlled-NOT gates using optimized stimulated Raman adiabatic passage techniques and optimal control theory
Olivier DulieuLaetitia BombleThierry RibeyreMichèle Desouter-lecomteMichèle Desouter-lecomteDominique Sugnysubject
Physics010304 chemical physicsField (physics)Stimulated Raman adiabatic passageRotational–vibrational spectroscopyOptimal control01 natural sciencesAtomic and Molecular Physics and OpticsControlled NOT gateQuantum mechanics0103 physical sciencesPhysics::Atomic and Molecular ClustersTime domain010306 general physicsAdiabatic processQuantum computerdescription
Implementation of quantum controlled-NOT (CNOT) gates in realistic molecular systems is studied using stimulated Raman adiabatic passage (STIRAP) techniques optimized in the time domain by genetic algorithms or coupled with optimal control theory. In the first case, with an adiabatic solution (a series of STIRAP processes) as starting point, we optimize in the time domain different parameters of the pulses to obtain a high fidelity in two realistic cases under consideration. A two-qubit CNOT gate constructed from different assignments in rovibrational states is considered in diatomic (NaCs) or polyatomic $({\text{SCCl}}_{2})$ molecules. The difficulty of encoding logical states in pure rotational states with STIRAP processes is illustrated. In such circumstances, the gate can be implemented by optimal control theory and the STIRAP sequence can then be used as an interesting trial field. We discuss the relative merits of the two methods for rovibrational computing (structure of the control field, duration of the control, and efficiency of the optimization).
| year | journal | country | edition | language |
|---|---|---|---|---|
| 2009-10-23 | Physical Review A |