Different types of photon entanglement from a constantly driven quantum
emitter inside a cavity
- URL: http://arxiv.org/abs/2008.10234v1
- Date: Mon, 24 Aug 2020 07:28:04 GMT
- Title: Different types of photon entanglement from a constantly driven quantum
emitter inside a cavity
- Authors: Tim Seidelmann, Michael Cosacchi, Moritz Cygorek, Doris E. Reiter,
Alexei Vagov, Vollrath Martin Axt
- Abstract summary: Bell states are the most prominent maximally entangled photon states.
In a typical four-level emitter, like a semiconductor quantum dot, the photon states exhibit only one type of Bell state entanglement.
By adding an external driving to the emitter system, also other types of Bell state entanglement are reachable without changing the polarization basis.
- Score: 0.0
- License: http://arxiv.org/licenses/nonexclusive-distrib/1.0/
- Abstract: Bell states are the most prominent maximally entangled photon states. In a
typical four-level emitter, like a semiconductor quantum dot, the photon states
exhibit only one type of Bell state entanglement. By adding an external driving
to the emitter system, also other types of Bell state entanglement are
reachable without changing the polarization basis. In this paper, we show under
which conditions the different types of entanglement occur and give analytical
equations to explain these findings. We further identify special points, where
the concurrence, being a measure for the degree of entanglement, drops to zero,
while the coherences between the two-photon states stay strong. Results of this
work pave the way to achieve a controlled manipulation of the entanglement type
in practical devices.
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