Author:
Li Jin-Fang,Hu Jie-Ru,Wan Feng,He Dong-Shan
Abstract
AbstractImplementation of quantum gates are important for quantum computations in physical system made of polar molecules. We investigate the feasibility of implementing gates based on pendular states of the molecular system by two different quantum optical control methods. Firstly, the Multi-Target optimal control theory and the Multi-Constraint optimal control theory are described for optimizing control fields and accomplish the optimization of quantum gates. Numerical results show that the controlled NOT gate (CNOT) can be realized under the control of above methods with high fidelities (0.975 and 0.999) respectively. In addition, in order to examine the dependence of the fidelity on energy difference in the same molecular system, the SWAP gate in the molecular system is also optimized with high fidelity (0.999) by the Multi-Constraint optimal control theory with the zero-area and constant-fluence constraints.
Funder
The Natural Science Foundation of Shaanxi Province
The Scientific Research Foundation of Xianyang Normal University
Publisher
Springer Science and Business Media LLC
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