1,009 research outputs found
Angular Schmidt Modes in Spontaneous Parametric Down-Conversion
We report a proof-of-principle experiment demonstrating that appropriately
chosen set of Hermite-Gaussian modes constitutes a Schmidt decomposition for
transverse momentum states of biphotons generated in the process of spontaneous
parametric down conversion. We experimentally realize projective measurements
in Schmidt basis and observe correlations between appropriate pairs of modes.
We perform tomographical state reconstruction in the Schmidt basis, by direct
measurement of single-photon density matrix eigenvalues.Comment: 5 pages, 4 figure
Triggered qutrits for Quantum Communication protocols
A general protocol in Quantum Information and Communication relies in the
ability of producing, transmitting and reconstructing, in general, qunits. In
this letter we show for the first time the experimental implementation of these
three basic steps on a pure state in a three dimensional space, by means of the
orbital angular momentum of the photons. The reconstruction of the qutrit is
performed with tomographic techniques and a Maximum-Likelihood estimation
method. In this way we also demonstrate that we can perform any transformation
in the three dimensional space
Probing quantum coherence in qubit arrays
We discuss how the observation of population localization effects in
periodically driven systems can be used to quantify the presence of quantum
coherence in interacting qubit arrays. Essential for our proposal is the fact
that these localization effects persist beyond tight-binding Hamiltonian
models. This result is of special practical relevance in those situations where
direct system probing using tomographic schemes becomes infeasible beyond a
very small number of qubits. As a proof of principle, we study analytically a
Hamiltonian system consisting of a chain of superconducting flux qubits under
the effect of a periodic driving. We provide extensive numerical support of our
results in the simple case of a two-qubits chain. For this system we also study
the robustness of the scheme against different types of noise and disorder. We
show that localization effects underpinned by quantum coherent interactions
should be observable within realistic parameter regimes in chains with a larger
number o
Measuring vertebrate telomeres: applications and limitations
Telomeres are short tandem repeated sequences of DNA found at the ends of eukaryotic
chromosomes that function in stabilizing chromosomal end integrity.
In vivo
studies of
somatic tissue of mammals and birds have shown a correlation between telomere length and
organismal age within species, and correlations between telomere shortening rate and
lifespan among species. This result presents the tantalizing possibility that telomere length
could be used to provide much needed information on age, ageing and survival in natural
populations where longitudinal studies are lacking. Here we review methods available for
measuring telomere length and discuss the potential uses and limitations of telomeres as
age and ageing estimators in the fields of vertebrate ecology, evolution and conservation
Optimal quantum cloning of orbital angular momentum photon qubits via Hong-Ou-Mandel coalescence
The orbital angular momentum (OAM) of light, associated with a helical
structure of the wavefunction, has a great potential for quantum photonics, as
it allows attaching a higher dimensional quantum space to each photon.
Hitherto, however, the use of OAM has been hindered by its difficult
manipulation. Here, exploiting the recently demonstrated spin-OAM information
transfer tools, we report the first observation of the Hong-Ou-Mandel
coalescence of two incoming photons having nonzero OAM into the same outgoing
mode of a beam-splitter. The coalescence can be switched on and off by varying
the input OAM state of the photons. Such effect has been then exploited to
carry out the 1 \rightarrow 2 universal optimal quantum cloning of OAM-encoded
qubits, using the symmetrization technique already developed for polarization.
These results are finally shown to be scalable to quantum spaces of arbitrary
dimension, even combining different degrees of freedom of the photons.Comment: 5 pages, 3 figure
Vibrational excitons in ionophores: Experimental probes for quantum coherence-assisted ion transport and selectivity in ion channels
Despite a large body of work, the exact molecular details underlying
ion-selectivity and transport in the potassium channel have not been fully laid
to rest. One major reason has been the lack of experimental methods that can
probe these mechanisms dynamically on their biologically relevant time scales.
Recently it was suggested that quantum coherence and its interplay with thermal
vibration might be involved in mediating ion-selectivity and transport. In this
work we present an experimental strategy for using time resolved infrared
spectroscopy to investigate these effects. We show the feasibility by
demonstrating the IR absorption and Raman spectroscopic signatures of potassium
binding model molecules that mimic the transient interactions of potassium with
binding sites of the selectivity filter during ion conduction. In addition to
guide our experiments on the real system we have performed molecular
dynamic-based simulations of the FTIR and 2DIR spectra of the entire KcsA
complex, which is the largest complex for which such modeling has been
performed. We found that by combing isotope labeling with 2D IR spectroscopy,
the signatures of potassium interaction with individual binding sites would be
experimentally observable and identified specific labeling combinations that
would maximize our expected experimental signatures
Wigner function for twisted photons
A comprehensive theory of the Weyl-Wigner formalism for the canonical pair
angle-angular momentum is presented, with special emphasis in the implications
of rotational periodicity and angular-momentum discreteness.Comment: 6 pages, 4 figure
- …