1,246 research outputs found
Studies of fiber-matrix adhesion on compression strength
A study was initiated on the effect of the matrix polymer and the fiber matrix bond strength of carbon fiber polymer matrix composites. The work includes tests with micro-composites, single ply composites, laminates, and multi-axial loaded cylinders. The results obtained thus far indicate that weak fiber-matrix adhesion dramatically reduces 0 degree compression strength. Evidence is also presented that the flaws in the carbon fiber that govern compression strength differ from those that determine fiber tensile strength. Examination of post-failure damage in the single ply tests indicates kink banding at the crack tip
On the Lagrangian structure of 3D consistent systems of asymmetric quad-equations
Recently, the first-named author gave a classification of 3D consistent
6-tuples of quad-equations with the tetrahedron property; several novel
asymmetric 6-tuples have been found. Due to 3D consistency, these 6-tuples can
be extended to discrete integrable systems on Z^m. We establish Lagrangian
structures and flip-invariance of the action functional for the class of
discrete integrable systems involving equations for which some of the
biquadratics are non-degenerate and some are degenerate. This class covers,
among others, some of the above mentioned novel systems.Comment: 21 pp, pdfLaTe
Femtosecond photoelectron diffraction: A new approach to image molecular structure during photochemical reactions.
Continuing technical advances in the creation of (sub-) femtosecond VUV and X-ray pulses with Free-Electron Lasers and laser-based high-harmonic-generation sources have created new opportunities for studying ultrafast dynamics during chemical reactions. Here, we present an approach to image the geometric structure of gas-phase molecules with fewfemtosecond temporal and sub-Γ
ngstrΓΆm spatial resolution using femtosecond photoelectron diffraction. This technique allows imaging the molecules βfrom withinβ by analyzing the diffraction of inner-shell photoelectrons that are created by femtosecond VUV and X-ray pulses. Using pump-probe schemes, ultrafast structural changes during photochemical reactions can thus be directly visualized with a temporal resolution that is only limited by the pulse durations of the pump and the probe pulse and the synchronization of the two light pulses. Here, we illustrate the principle of photoelectron diffraction using a simple, geometric scattering model and present results from photoelectron diffraction experiments on laser-aligned molecules using X-ray pulses from a Free-Electron Laser
Blind Normalization of Speech From Different Channels
We show how to construct a channel-independent representation of speech that
has propagated through a noisy reverberant channel. This is done by blindly
rescaling the cepstral time series by a non-linear function, with the form of
this scale function being determined by previously encountered cepstra from
that channel. The rescaled form of the time series is an invariant property of
it in the following sense: it is unaffected if the time series is transformed
by any time-independent invertible distortion. Because a linear channel with
stationary noise and impulse response transforms cepstra in this way, the new
technique can be used to remove the channel dependence of a cepstral time
series. In experiments, the method achieved greater channel-independence than
cepstral mean normalization, and it was comparable to the combination of
cepstral mean normalization and spectral subtraction, despite the fact that no
measurements of channel noise or reverberations were required (unlike spectral
subtraction).Comment: 25 pages, 7 figure
Two-color polarization control on angularly resolved attosecond time delays
Measured photoionization time delays may exhibit large variations as a
function of the emission angles, even for spherically symmetric targets, as
shown in recent RABBITT (reconstruction of attosecond beating by interference
of two-photon transitions) experiments. The contributions from different
pathways to the two-photon quantum channels can already explain the observed
phase jumps that shape those angular distributions. Here, we propose a simple
analytical model to describe angularly-resolved RABBITT spectra as a function
of the relative polarization angle between the ionizing attosecond pulse train
and the assisting IR field. We demonstrate that the angular dependencies of the
measured delays can be analytically predicted and the position of the phase
jumps reduced to the analysis of a few relevant parameters.Comment: 10 pages, 4 figure
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