6,905 research outputs found
Shearing Interferometer for Quantifying the Coherence of Hard X-Ray Beams
We report a quantitative measurement of the full transverse coherence function of the 14.4 keV x-ray radiation produced by an undulator at the Swiss Light Source. An x-ray grating interferometer consisting of a beam splitter phase grating and an analyzer amplitude grating has been used to measure the degree of coherence as a function of the beam separation out to 30 m. Importantly, the technique provides a model-free and spatially resolved measurement of the complex coherence function and is not restricted to high resolution detectors and small fields of view. The spatial characterization of the wave front has important applications in discovering localized defects in beam line optics
Dynamic 3D shape measurement based on the phase-shifting moir\'e algorithm
In order to increase the efficiency of phase retrieval,Wang proposed a
high-speed moire phase retrieval method.But it is used only to measure the tiny
object. In view of the limitation of Wang method,we proposed a dynamic
three-dimensional (3D) measurement based on the phase-shifting moire
algorithm.First, four sinusoidal fringe patterns with a pi/2 phase-shift are
projected on the reference plane and acquired four deformed fringe patterns of
the reference plane in advance. Then only single-shot deformed fringe pattern
of the tested object is captured in measurement process.Four moire fringe
patterns can be obtained by numerical multiplication between the the AC
component of the object pattern and the AC components of the reference patterns
respectively. The four low-frequency components corresponding to the moire
fringe patterns are calculated by the complex encoding FT (Fourier transform)
,spectrum filtering and inverse FT.Thus the wrapped phase of the object can be
determined in the tangent form from the four phase-shifting moire fringe
patterns using the four-step phase shifting algorithm.The continuous phase
distribution can be obtained by the conventional unwrapping algorithm. Finally,
experiments were conducted to prove the validity and feasibility of the
proposed method. The results are analyzed and compared with those of Wang
method, demonstrating that our method not only can expand the measurement
scope, but also can improve accuracy.Comment: 14 pages,5 figures. ams.or
Full-field optical measurement of curvatures in ultra-thin-filmâsubstrate systems in the range of geometrically nonlinear deformations
This article describes coherent gradient sensing (CGS) as an optical, full-field, real-time, nonintrusive, and noncontact technique for the measurement of curvatures and nonuniform curvature changes in film-substrate systems. The technique is applied to the study of curvature fields in thin Al films (6 mum) deposited on thin circular silicon wafers (105 mum) of "large" in-plane dimensions (50.8 mm in diameter) subjected to thermal loading histories. The loading and geometry is such that the system experiences deformations that are clearly within the nonlinear range. The discussion is focused on investigating the limits of the range of the linear relationship between the thermally induced mismatch strain and the substrate curvature, on the degree to which the substrate curvature becomes spatially nonuniform in the range of geometrically nonlinear deformation, and finally, on the bifurcation of deformation mode from axial symmetry to asymmetry with increasing mismatch strain. Results obtained on the basis of both simple models and more-detailed finite-element simulations are compared with the full-field CGS measurements with the purpose of validating the analytical and numerical models
Thermal expansion of composites using Moire interferometry
An experimental technique for precise measurement of the thermal response of fiber-reinforced composite materials uses moire interferometry with fringe multiplication which yield a sensitivity of 833 nm (32.8 mu in.) per fringe. Results from the technique are compared with those obtained from electrical resistance strain gages, and also those predicted from classical lamination theory. Temperature dependent coefficients of thermal expansion for composite materials subjected to thermal cycling in the temperature range of 297 K (75 F) to 422 K (300 F) were determined for four laminate configurations (0, 90, 0/ + or - 45/90 sub s and 0/90/ + or - 45 sub s) of T300/5208 graphite epoxy, and ranged from -0.107 mu epsilon K/1 (-0.059 mu epsilon deg F/-) for the 0 laminate to 32.18 mu epsilon K/1 (17.88 mu epsilon F/1) for the 90 laminate. Moisture was found to greatly influence the thermal response of a quasi-isotropic laminate, resulting in hysteresis and residual compressive strain as the moisture content was reduced. Comparisons between moire and strain gage measurements were inconclusive with both techniques giving consistent but systematically different results. Differences of as much as 29% were observed
Fiber Bragg Grating sensors for deformation monitoring of GEM foils in HEP detectors
Fiber Bragg Grating (FBG) sensors have been so far mainly used in high energy
physics (HEP) as high precision positioning and re-positioning sensors and as
low cost, easy to mount, radiation hard and low space- consuming temperature
and humidity devices. FBGs are also commonly used for very precise strain
measurements. In this work we present a novel use of FBGs as flatness and
mechanical tensioning sensors applied to the wide Gas Electron Multiplier (GEM)
foils of the GE1/1 chambers of the Compact Muon Solenoid (CMS) experiment at
Large Hadron Collider (LHC) of CERN. A network of FBG sensors has been used to
determine the optimal mechanical tension applied and to characterize the
mechanical stress applied to the foils. The preliminary results of the test
performed on a full size GE1/1 final prototype and possible future developments
will be discussed.Comment: Four pages, seven figures. Presented by Michele Caponero at IWASI
2015, Gallipoli (Italy
A nanofabricated, monolithic, path-separated electron interferometer
We report a self-aligned, monolithic electron interferometer, consisting of
two 45 nm thick silicon layers separated by 20 m. This interferometer was
fabricated from a single crystal silicon cantilever on a transmission electron
microscope grid by gallium focused ion-beam milling. Using this interferometer,
we demonstrate beam path-separation, and obtain interference fringes in a
Mach-Zehnder geometry, in an unmodified 200 kV transmission electron
microscope. The fringes have a period of 0.32 nm, which corresponds to the
lattice planes of silicon, and a maximum
contrast of 15 %. This design can potentially be scaled to millimeter-scale,
and used in electron holography. It can also be applied to perform fundamental
physics experiments, such as interaction-free measurement with electrons.Comment: 21 pages (including supplementary info), 8 figures; Corrected typos,
added references for introduction and conclusion, changed ordering of
paragraphs of Discussion, results unchange
75%-efficiency blue generation from an intracavity PPKTP frequency doubler
We report on a high-efficiency 461 nm blue light conversion from an external
cavity-enhanced second-harmonic generation of a 922 nm diode laser with a
quasi-phase-matched KTP crystal (PPKTP). By choosing a long crystal (LC=20 mm)
and twice looser focusing (w0=43 m) than the "optimal" one, thermal
lensing effects due to the blue power absorption are minimized while still
maintaining near-optimal conversion efficiency. A stable blue power of 234 mW
with a net conversion efficiency of eta=75% at an input mode-matched power of
310 mW is obtained. The intra-cavity measurements of the conversion efficiency
and temperature tuning bandwidth yield an accurate value d33(461 nm)=15 pm/V
for KTP and provide a stringent validation of some recently published linear
and thermo-optic dispersion data of KTP
Fatigue Damage in Notched Composite Laminates Under Tension-Tension Cyclic Loads
The results are given of an investigation to determine the damage states which develop in graphite epoxy laminates with center holes due to tension-tension cyclic loads, to determine the influence of stacking sequence on the initiation and interaction of damage modes and the process of damage development, and to establish the relationships between the damage states and the strength, stiffness, and life of the laminates. Two quasi-isotropic laminates were selected to give different distributions of interlaminar stresses around the hole. The laminates were tested under cyclic loads (R=0.1, 10 Hz) at maximum stresses ranging between 60 and 95 percent of the notched tensile strength
Interferometric method for determining the sum of the flexoelectric coefficients (e1+e3) in an ionic nematic material
The time-dependent periodic distortion profile in a nematic liquid crystal phase grating has been measured from the displacement of tilt fringes in a Mach-Zehnder interferometer. A 0.2âHz squarewave voltage was applied to alternate stripe electrodes in an interdigitated electrode geometry. The time-dependent distortion profile is asymmetric with respect to the polarity of the applied voltage and decays with time during each half period due to ionic shielding. This asymmetry in the response allows the determination of the sum of the flexoelectric coefficients (e1+e3) using nematic continuum theory since the device geometry does not possess inherent asymmetry
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