248 research outputs found
Security of Continuous Variable Quantum Cryptography
We discuss a quantum key distribution scheme in which small phase and
amplitude modulations of CW light beams carry the key information. The presence
of EPR type correlations provides the quantum protection. We identify universal
constraints on the level of shared information between the intended receiver
(Bob) and any eavesdropper (Eve) and use this to make a general evaluation of
security. We identify teleportation as an optimum eavesdropping technique.Comment: 6 figure
Fabrication and deterministic transfer of high quality quantum emitter in hexagonal boron nitride
Color centers in solid state crystals have become a frequently used system
for single photon generation, advancing the development of integrated photonic
devices for quantum optics and quantum communication applications. In
particular, defects hosted by two-dimensional (2D) hexagonal boron nitride
(hBN) are a promising candidate for next-generation single photon sources, due
to its chemical and thermal robustness and high brightness at room temperature.
The 2D crystal lattice of hBN allows for a high extraction efficiency and easy
integration into photonic circuits. Here we develop plasma etching techniques
with subsequent high temperature annealing to reliably create defects. We show
how different fabrication parameters influence the defect formation probability
and the emitter brightness. A full optical characterization reveals the higher
quality of the created quantum emitters, represented by a narrow spectrum,
short excited state lifetime and high single photon purity. We also
investigated the photostability on short and very long timescales. We utilize a
wet chemically-assisted transfer process to reliably transfer the single photon
sources onto arbitrary substrates, demonstrating the feasibility for the
integration into scalable photonic quantum information processing networks.Comment: revised versio
Multimode laser cooling and ultra-high sensitivity force sensing with nanowires
Photo-induced forces can be used to manipulate and cool the mechanical motion
of oscillators. When the oscillator is used as a force sensor, such as in
atomic force microscopy, active feedback is an enticing route to enhancing
measurement performance. Here, we show broadband multimode cooling of dB
down to a temperature of ~K in the stationary regime. Through the use
of periodic quiescence feedback cooling, we show improved signal-to-noise
ratios for the measurement of transient signals. We compare the performance of
real feedback to numerical post-processing of data and show that both methods
produce similar improvements to the signal-to-noise ratio of force
measurements. We achieved a room temperature force measurement sensitivity of
N with integration time of less than ms. The high
precision and fast force microscopy results presented will potentially benefit
applications in biosensing, molecular metrology, subsurface imaging and
accelerometry.Comment: 16 pages and 3 figures for the main text, 14 pages and 5 figures for
the supplementary informatio
Quantum Cloning of Continuous Variable Entangled States
We consider the quantum cloning of continuous variable entangled states. This
is achieved by introducing two symmetric entanglement cloning machines (or
e-cloners): a local e-cloner and a global e-cloner; where we look at the
preservation of entanglement in the clones under the condition that the
fidelity of the clones is maximized. These cloning machines are implemented
using simple linear optical elements such as beam splitters and homodyne
detection along with squeeze gates. We show that the global e-cloner
out-performs the local e-cloner both in terms of the fidelity of the cloned
states as well as the strength of the entanglement of the clones. There is a
minimum strength of entanglement (3dB for the inseparability criterion and
5.7dB for the EPR paradox criterion) of the input state of the global e-cloner
that is required to preserve the entanglement in the clones.Comment: 11 pages, 6 figure
Gaussian Post-selection for Continuous Variable Quantum Cryptography
We extend the security proof for continuous variable quantum key distribution
protocols using post selection to account for arbitrary eavesdropping attacks
by employing the concept of an equivalent protocol where the post-selection is
implemented as a series of quantum operations including a virtual distillation.
We introduce a particular `Gaussian' post selection and demonstrate that the
security can be calculated using only experimentally accessible quantities.
Finally we explicitly evaluate the performance for the case of a noisy Gaussian
channel in the limit of unbounded key length and find improvements over all
pre-existing continuous variable protocols in realistic regimes.Comment: 4+4 pages. arXiv admin note: substantial text overlap with
arXiv:1106.082
Conditional quantum-state engineering using ancillary squeezed-vacuum states
We investigate an optical scheme to conditionally engineer quantum states
using a beam splitter, homodyne detection and a squeezed vacuum as an ancillar
state. This scheme is efficient in producing non-Gaussian quantum states such
as squeezed single photons and superpositions of coherent states (SCSs). We
show that a SCS with well defined parity and high fidelity can be generated
from a Fock state of , and conjecture that this can be generalized for
an arbitrary Fock state. We describe our experimental demonstration of this
scheme using coherent input states and measuring experimental fidelities that
are only achievable using quantum resources.Comment: 10 pages, 14 figures, use pdf version, high quality figures available
on reques
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