Jun Zhang
Published 2011-05-26, updated 2011-06-03Version 2
We show that the entanglement dynamics for a closed two-qubit system is part of a 10-dimensional complex linear differential equation defined on a supersphere, and the coefficients therein are completely determined by the Hamiltonian. We apply the result to investigate two physical examples of Josephson junction qubits and exchange Hamiltonians, deriving analytic solutions for the time evolution of entanglement. The Hamiltonian coefficients determines whether the entanglement is periodic. These results allow of investigating how to generate and manipulate entanglements efficiently, which are required by both quantum computation and quantum communication.
Comments: 5 pages
Journal: Quantum Information Processing, 12(4), 1627-1636, 2013
Comment on ``Resonant Spectra and the Time Evolution of the Survival and Nonescape Probabilities''
The Schroedinger equation as the time evolution of a deterministic and reversible process
Time evolution of entangled biatomic states in a cavity
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