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Negative energy density in superposition and entangled states

L.H. Ford
(
- Tufts U.
)
,
Thomas A. Roman
(
- Central Connecticut State U.
)

Feb 15, 2008

21 pages

Published in:

Phys.Rev.D 77 (2008) 045018

e-Print:

0705.3003 [quant-ph]

DOI:

10.1103/PhysRevD.77.045018

View in:

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Abstract: (arXiv)

We examine the maximum negative energy density which can be attained in various quantum states of a massless scalar field. We consider states in which either one or two modes are excited, and show that the energy density can be given in terms of a small number of parameters. We calculate these parameters for several examples of superposition states for one mode, and entangled states for two modes, and find the maximum magnitude of the negative energy density in these states. We consider several states which have been, or potentially will be, generated in quantum optics experiments.

Note:

21 pages, 5 figures

03.65.Ud
04.62.+v
42.50.Pq
field theory: scalar
massless
energy: density
energy: negative
coherent state
squeezed state
entanglement

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Figures(5)

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