171 research outputs found
High performance guided-wave asynchronous heralded single photon source
We report on a guided wave heralded photon source based on the creation of
non-degenerate photon pairs by spontaneous parametric down conversion in a
Periodically Poled Lithium Niobate waveguide. Using the signal photon at 1310
nm as a trigger, a gated detection process permits announcing the arrival of
single photons at 1550 nm at the output of a single mode optical fiber with a
high probability of 0.38. At the same time the multi-photon emission
probability is reduced by a factor of 10 compared to poissonian light sources.
Relying on guided wave technologies such as integrated optics and fiber optics
components, our source offers stability, compactness and efficiency and can
serve as a paradigm for guided wave devices applied to quantum communication
and computation using existing telecom networks
PPLN Waveguide for Quantum Communication
We report on energy-time and time-bin entangled photon-pair sources based on
a periodically poled lithium niobate (PPLN) waveguide. Degenerate twin photons
at 1314 nm wavelength are created by spontaneous parametric down-conversion and
coupled into standard telecom fibers. Our PPLN waveguide features a very high
conversion efficiency of about 10^(-6), roughly 4 orders of magnitude more than
that obtained employing bulk crystals. Even if using low power laser diodes,
this engenders a significant probability for creating two pairs at a time - an
important advantage for some quantum communication protocols. We point out a
simple means to characterize the pair creation probability in case of a pulsed
pump. To investigate the quality of the entangled states, we perform
photon-pair interference experiments, leading to visibilities of 97% for the
case of energy-time entanglement and of 84% for the case of time-bin
entanglement. Although the last figure must still be improved, these tests
demonstrate the high potential of PPLN waveguide based sources to become a key
element for future quantum communication schemesComment: 11 pages, 9 figures, submitted to the European Physical Journal D
(special issue of the Quick conference
A quantum relay chip based on telecommunication integrated optics technology
We investigate an integrated optical circuit on lithium niobate designed to
implement the teleportation-based quantum relay scheme for one-way quantum
communication at a telecom wavelength. Such an advanced quantum circuit merges
for the first time, both optical-optical and electro-optical non-linear
functions necessary to implement the desired on-chip single qubit
teleportation. On one hand, spontaneous parametric down-conversion is used to
produce entangled photon-pairs. On the other hand, we take advantage of two
photon routers, consisting of electro-optically controllable couplers, to
separate the paired photons and to perform a Bell state measurement,
respectively. After having validated all the individual functions in the
classical regime, we have performed a Hong-Ou-Mandel (HOM) experiment to mimic
a one-way quantum communication link. Such a quantum effect, seen as a
prerequisite towards achieving teleportation, has been obtained, at one of the
routers, when the chip was coupled to an external single photon source. The
two-photon interference pattern shows a net visibility of 80%, which validates
the proof of principle of a "quantum relay circuit" for qubits carried by
telecom photons. In case of optimized losses, such a chip could increase the
maximal achievable distance of one-way quantum key distribution links by a
factor 1.8. Our approach and results emphasize the high potential of integrated
optics on lithium niobate as a key technology for future reconfigurable quantum
information manipulation.Comment: 16 pages, 8 figure
Increased pump acceptance bandwidth in spontaneous parametric downconversion process using Bragg reflection waveguides
In this paper we show that by suitably tailoring the dispersion
characteristics of a Bragg reflection waveguide (BRW) mode, it is possible to
achieve efficient photon pair generation over a large pump bandwidth while
maintaining narrow signal bandwidth. The structure proposed consists of a high
index core BRW with a periodically poled GaN core and periodically stratified
cladding made up of alternate layers of and
. Such photon-pair generators should find applications in
realizing compact and stable sources for quantum information processing.Comment: 6 pages, 5 figure
High-visibilty two-photon interference at a telecom wavelength using picosecond regime separated sources
We report on a two-photon interference experiment in a quantum relay
configuration using two picosecond regime PPLN waveguide based sources emitting
paired photons at 1550 nm. The results show that the picosecond regime
associated with a guided-wave scheme should have important repercussions for
quantum relay implementations in real conditions, essential for improving both
the working distance and the efficiency of quantum cryptography and networking
systems. In contrast to already reported regimes, namely femtosecond and CW, it
allows achieving a 99% net visibility two-photon interference while maintaining
a high effective photon pair rate using only standard telecom components and
detectors.Comment: to appear in PRA as a rapid communicatio
Polarization entangled photon-pair source based on a type-II PPLN waveguide emitting at a telecom wavelength
We report the realization of a fiber coupled polarization entangled
photon-pair source at 1310 nm based on a birefringent titanium in-diffused
waveguide integrated on periodically poled lithium niobate. By taking advantage
of a dedicated and high-performance setup, we characterized the quantum
properties of the pairs by measuring two-photon interference in both
Hong-Ou-Mandel and standard Bell inequality configurations. We obtained, for
the two sets of measurements, interference net visibilities reaching nearly
100%, which represent important and competitive results compared to similar
waveguide-based configurations already reported. These results prove the
relevance of our approach as an enabling technology for long-distance quantum
communication.Comment: 13 pages, 4 figures, to appear in New Journal of Physic
Generation of polarization entangled photons using type-II doubly periodically poled lithium niobate waveguides
In this paper, we address the issue of the generation of non-degenerate
cross-polarization-entangled photon pairs using type-II periodically poled
lithium niobate. We show that, by an appropriate engineering of the
quasi-phase-matching grating, it is possible to simultaneously satisfy the
conditions for two spontaneous parametric down-conversion processes, namely
ordinary pump photon down-conversion to either extraordinary signal and
ordinary idler paired photons, or to ordinary signal and extraordinary idler
paired photons. In contrast to single type-II phase-matching, these two
processes, when enabled together, can lead to the direct production of
cross-polarization-entangled state for non degenerate signal and idler
wavelengths. Such a scheme should be of great interest in applications
requiring polarization-entangled non degenerate paired photons with, for
instance, one of the entangled photons at an appropriate wavelength being used
for local operation or for quantum storage in an atomic ensemble, and the other
one at the typical wavelength of 1550 nm for propagation through an optical
fiber.Comment: 9 pages, 5 figures, 2 table
Integrated optical source of polarization entangled photons at 1310 nm
We report the realization of a new polarization entangled photon-pair source
based on a titanium-indiffused waveguide integrated on periodically poled
lithium niobate pumped by a CW laser at . The paired photons are
emitted at the telecom wavelength of within a bandwidth of .
The quantum properties of the pairs are measured using a two-photon coalescence
experiment showing a visibility of 85%. The evaluated source brightness, on the
order of pairs , associated with its
compactness and reliability, demonstrates the source's high potential for
long-distance quantum communication.Comment: There is a typing mistake in the previous version in the visibility
equation. This mistake doesn't change the result
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