Quantum fidelity based on magnetic resonance force microscopy system

Abstract

Abstract: Under the different initial states, discuss the time evolution of the quantum state fidelity of C atom and H atom based on magnetic resonance force microscopy (MRFM) system. The results show that the time evolution curve of the fidelity is different under the different conditions of initial states. Both the deviation of the magnetic field due to the cantilever offset and the interaction of spins and RF magnetic field make the period of the fidelity decrease greatly. Consequently the quantum information can return its initial state in a short time interval. At the same time the RF magnetic field can make the quantum information approach ideal states in the transmission process that provides particular guidance for detecting atomic states in the sample and improving the accuracy of information in transmission process.

Key words: quantum optics, fidelity, magnetic resonance force microscopy, cantilever offset, radio frequency magnetic field

CLC Number:

O431.2

References

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