J. P. Coe, A. Sudbery, I. D'Amico
Published 2007-12-21, updated 2010-08-03Version 3
We present two methods of calculating the spatial entanglement of an interacting electron system within the framework of density-functional theory. These methods are tested on the model system of Hooke's atom for which the spatial entanglement can be calculated exactly. We analyse how the strength of the confining potential affects the spatial entanglement and how accurately the methods that we introduced reproduce the exact trends. We also compare the results with the outcomes of standard first-order perturbation methods. The accuracies of energies and densities when using these methods are also considered.
Comments: 14 pages with 18 figures; corrected typos, corrected expression for first-order energy in section VI and consequently Fig.13, conclusions and other results unaffected
Journal: Phys. Rev. B 77, 205122 (2008)
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