13,879 research outputs found
Simultaneous control of volumetric light distribution through turbid media using real-time three-dimensional optoacoustic feedback
Focusing light through turbid media presents a highly fascinating challenge
in modern biophotonics. The unique capability of optoacoustics for high
resolution imaging of light absorption contrast in deep tissues can provide a
natural and efficient feedback to control light delivery in scattering medium.
While basic feasibility of using optoacoustic readings as a feedback mechanism
for wavefront shaping has been recently reported, the suggested approaches may
require long acquisition times making them challenging to be translated into
realistic tissue environments. In an attempt to significantly accelerate
dynamic wavefront shaping capabilities, we present here a feedback-based
approach using real-time three-dimensional optoacoustic imaging assisted with
genetic-algorithm-based optimization. The new technique offers robust
performance in the presence of noisy measurements and can simultaneously
control the scattered wave field in an entire volumetric region.Comment: 4 pages, 3 figure
Influence of the absorber dimensions on wavefront shaping based on volumetric optoacoustic feedback
The recently demonstrated control over light distribution through turbid
media based on real-time three-dimensional optoacoustic feedback has offered
promising prospects to interferometrically focus light within scattering
objects. Nevertheless, the focusing capacity of the feedback-based approach is
strongly conditioned by the number of effectively resolvable optical modes
(speckles). In this letter, we experimentally tested the light intensity
enhancement achieved with optoacoustic feedback measurements from different
sizes of absorbing microparticles. The importance of the obtained results is
discussed in the context of potential signal enhancement at deep locations
within a scattering medium where the effective speckle sizes approach the
minimum values dictated by optical diffraction
Dynamics of Vibrated Granular Monolayers
We study statistical properties of vibrated granular monolayers using
molecular dynamics simulations. We show that at high excitation strengths, the
system is in a gas state, particle motion is isotropic, and the velocity
distributions are Gaussian. As the vibration strength is lowered the system's
dimensionality is reduced from three to two. Below a critical excitation
strength, a gas-cluster phase occurs, and the velocity distribution becomes
bimodal. In this phase, the system consists of clusters of immobile particles
arranged in close-packed hexagonal arrays, and gas particles whose energy
equals the first excited state of an isolated particle on a vibrated plate.Comment: 4 pages, 6 figs, revte
Giant spin-dependent photo-conductivity in GaAsN dilute nitride semiconductor
A theoretical and experimental study of the spin-dependent photoconductivity
in dilute Nitride GaAsN is presented. The non linear transport model we develop
here is based on the rate equations for electrons, holes, deep paramagnetic and
non paramagnetic centers both under CW and pulsed optical excitation. Emphasis
is given to the effect of the competition between paramagnetic centers and non
paramagnetic centers which allows us to reproduce the measured characteristics
of the spin-dependent recombination power dependence. Particular attention is
paid to the role of an external magnetic field in Voigt geometry. The
photoconductivity exhibits a Hanle-type curve whereas the spin polarization of
electrons shows two superimposed Lorentzian curves with different widths,
respectively related to the recombination of free and trapped electrons. The
model is capable of reproducing qualitatively and quantitatively the most
important features of photoluminescence and photocurrent experiments and is
helpful in providing insight on the various mechanisms involved in the electron
spin polarization and filtering in GaAsN semiconductors.Comment: 10 pages, 5 figure
Dynamical Scaling from Multi-Scale Measurements
We present a new measure of the Dynamical Critical behavior: the "Multi-scale
Dynamical Exponent (MDE)"Comment: 9 pages,Latex, Request figures from [email protected]
Room temperature Giant Spin-dependent Photoconductivity in dilute nitride semiconductors
By combining optical spin injection techniques with transport spectroscopy
tools, we demonstrate a spin-photodetector allowing for the electrical
measurement and active filtering of conduction band electron spin at room
temperature in a non-magnetic GaAsN semiconductor structure. By switching the
polarization of the incident light from linear to circular, we observe a Giant
Spin-dependent Photoconductivity (GSP) reaching up to 40 % without the need of
an external magnetic field. We show that the GSP is due to a very efficient
spin filtering effect of conduction band electrons on Nitrogen-induced Ga
self-interstitial deep paramagnetic centers.Comment: 4 pages, 3 figure
Structure de verres de silicophosphate dopés europium : analyse par spectroscopie optique et simulation de dynamique moléculaire
National audienc
Numerical modeling and measurement by pulsed television holography of ultrasonic displacement maps in plates with through-thickness defects
We present a novel numerical modeling of ultrasonic Lamb and Rayleigh wave propagation and scattering by through-thickness defects like holes and slots in homogeneous plates, and its experimental verification in both near and far field by a self-developed pulsed TV holography system. In contrast to rigorous vectorial formulation of elasticity theory, our model is based on the 2-D scalar wave equation over the plate surface, with specific boundary conditions in the defects and plate edges. The experimental data include complex amplitude maps of the out-of-plane displacements of the plate surface, obtained by a two-step spatiotemporal Fourier transform method. We find a fair match between the numerical and experimental results, which allows for quantitative characterization of the defects
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