Abstract
We study the dynamics of a system comprised of a single qubit interacting equally with qubits (a “spin star” system). Although this model can be solved exactly, the exact solution does not give much intuition for the dynamics of the model. Here, we find an approximation that gives some insight into the dynamics for a particular class of initial spin-coherent states of the qubits. We find an effective Hamiltonian for the system that is a finite Kerr (one-axis twisting) Hamiltonian for the qubits. The initial spin-coherent state evolves to spin-squeezed states on short time scales, and to “multiple-Schrödinger-cat” states (superpositions of many spin-coherent states) on longer time scales, a manifestation of the phenomenon of fractional revivals of the initial state. The evolution of the system is visualized with phase-space plots ( functions) that, when plotted against time, reveal a “quantum carpet” pattern. Of particular interest is the fact that our approximation captures the qualitative features of the model even for small values of . This suggests the possibility of observing the phenomenon of fractional revival in this model for systems of few qubits.
- Received 24 April 2014
DOI:https://doi.org/10.1103/PhysRevA.90.012320
©2014 American Physical Society