4 research outputs found
Distilling Quantum Entanglement via Mode-Matched Filtering
We propose a new avenue towards distillation of quantum entanglement that is
implemented by directly passing the entangled qubits through a mode-matched
filter. This approach can be applied to a common class of entanglement
impurities appearing in photonic systems where the impurities inherently occupy
different spatiotemporal modes than the entangled qubits. As a specific
application, we show that our method can be used to significantly purify the
telecom-band entanglement generated via the Kerr nonlinearity in single-mode
fibers where a substantial amount of Raman-scattering noise is concomitantly
produced.Comment: 6 pages, 2 figures, to appear in Phys. Rev.
Heralding Single Photons Without Spectral Factorability
Recent efforts to produce single photons via heralding have relied on
creating spectrally factorable two-photon states in order to achieve both high
purity and high production rate. Through a careful multimode analysis, we find,
however, that spectral factorability is not necessary. Utilizing single-mode
detection, a similar or better performance can be achieved with non-factorable
states. This conclusion rides on the fact that even when using a broadband
filter, a single-mode measurement can still be realized, as long as the
coherence time of the triggering photons exceeds the measurement window of the
on/off detector.Comment: 7 pages, 5 figure
Erasing Quantum Distinguishability via Single-Mode Filtering
Erasing quantum-mechanical distinguishability is of fundamental interest and
also of practical importance, particularly in subject areas related to quantum
information processing. We demonstrate a method applicable to optical systems
in which single-mode filtering is used with only linear optical instruments to
achieve quantum indistinguishability. Through "heralded" Hong-Ou-Mandel
interference experiments we measure and quantify the improvement of
indistinguishability between single photons generated via spontaneous four-wave
mixing in optical fibers. The experimental results are in excellent agreement
with predictions of a quantum-multimode theory we develop for such systems,
without the need for any fitting parameter.Comment: 5 pages, 5 figure