https://doi.org/10.1140/epjd/e2009-00286-2
Entanglement dynamics in two-qubit open system interacting with a squeezed thermal bath via quantum nondemolition interaction
1
Raman Research Institute, 560080 Bangalore, India
2
Chennai Mathematical Institute, Padur PO, 603103 Siruseri, India
3
Indian Institute of Technology, Kanpur, India
4
Poornaprajna Institute of Scientific Research,
560080 Bangalore, India
Corresponding authors: subhashish@cmi.ac.in vravi@iitk.ac.in srik@ppisr.res.in
Received:
22
July
2009
Revised:
23
September
2009
Published online:
17
November
2009
We analyze the dynamics of entanglement in a two-qubit system
interacting with an initially squeezed thermal environment via a
quantum nondemolition system-reservoir interaction, with the system
and reservoir assumed to be initially separable. We compare and
contrast the decoherence of the two-qubit system in the case where
the qubits are mutually close-by (`collective regime') or distant
(`localized regime') with respect to the spatial variation of the
environment. Sudden death of entanglement (as quantified by
concurrence) is shown to occur in the localized case rather than in
the collective case, where entanglement tends to `ring down'.
A consequence of the QND character of the interaction is that the
time-evolved fidelity of a Bell state never falls below 
,
a fact that is useful for quantum communication applications
like a quantum repeater. Using
a novel quantification of mixed state entanglement, we show that
there are noise regimes where even though entanglement
vanishes, the state is still available for
applications like NMR quantum computation, because of the presence
of a pseudo-pure component.
PACS: 03.65.Yz – Decoherence; open systems; quantum statistical method / 03.67.Mn – Entanglement measures, witnesses, and other characterizations / 03.67.Bg – Entanglement production and manipulation / 03.67.Hk – Quantum communication
© EDP Sciences, Società Italiana di Fisica, Springer-Verlag, 2009
