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Schematic of experimental setup

Fig. 1 Schematic of experimental setup used for TOFD measurements. Fig. 1 Schematic of experimental setup used for TOFD measurements.
FIGURE 6.7 (a) Schematics of experimental setup used for in vivo resonance Raman imaging, RRI, of MP... [Pg.96]

Figure 6.7. Schematic of experimental setup of a LDVS measurement system for local size, velocity, and number flow density of droplets in the spray cone during spray deposition of a liquid steel. (Reprinted from Ref. 615.)... Figure 6.7. Schematic of experimental setup of a LDVS measurement system for local size, velocity, and number flow density of droplets in the spray cone during spray deposition of a liquid steel. (Reprinted from Ref. 615.)...
Fig. 1. Schematic of experimental setup. %J2 - 800 nm wave-plate SP 2-mm sapphire plate PI, 2 45° quartz prisms P3 69° quartz prism, the distance from P3 to the NOPA crystal is 80 cm CM1, 2 ultrabroadband chirped mirrors GR 300 lines/mm ruled diffraction grating (Jobin Yvon) SM spherical mirror, R=-400 mm BS1, 2 chromium-coated d=0.5 mm quartz beam splitters. SHG crystal 0.4-mm 0=29° BBO (EKSMA) NOPA crystal 1-mm 0=31.5° BBO (Casix) SHG FROG crystal 0=29° BBO wedge plate d=5- -20 pm (EKSMA). Spherical mirrors around NOPA crystal are R=-200 mm Thick arrows on the left indicate the data flow from the pulse diagnostic setup (SHG FROG) and the feedback to the flexible mirror. Fig. 1. Schematic of experimental setup. %J2 - 800 nm wave-plate SP 2-mm sapphire plate PI, 2 45° quartz prisms P3 69° quartz prism, the distance from P3 to the NOPA crystal is 80 cm CM1, 2 ultrabroadband chirped mirrors GR 300 lines/mm ruled diffraction grating (Jobin Yvon) SM spherical mirror, R=-400 mm BS1, 2 chromium-coated d=0.5 mm quartz beam splitters. SHG crystal 0.4-mm 0=29° BBO (EKSMA) NOPA crystal 1-mm 0=31.5° BBO (Casix) SHG FROG crystal 0=29° BBO wedge plate d=5- -20 pm (EKSMA). Spherical mirrors around NOPA crystal are R=-200 mm Thick arrows on the left indicate the data flow from the pulse diagnostic setup (SHG FROG) and the feedback to the flexible mirror.
Figure 1. Schematic of experimental setup for measurements of the rotating ring-disk electrode (1) dual potentiogal-vanostat (2) ZnO disk electrode (3) Pt ring electrode (4) Teflon electrode holder (5) electrolytic cell (6) N2 gas inlet (7) Pt counter electrode (8) SCE (9) mirror ... Figure 1. Schematic of experimental setup for measurements of the rotating ring-disk electrode (1) dual potentiogal-vanostat (2) ZnO disk electrode (3) Pt ring electrode (4) Teflon electrode holder (5) electrolytic cell (6) N2 gas inlet (7) Pt counter electrode (8) SCE (9) mirror ...
Figure 18 Schematic of experimental setup for measurement of 3D bubble deformation and flow structure in the wake using the combination of PIV/LIF and double-SIT (a) schematic of the measurement system and (b) top view of the experimental facility (Fujiwara et al., 2004a). Figure 18 Schematic of experimental setup for measurement of 3D bubble deformation and flow structure in the wake using the combination of PIV/LIF and double-SIT (a) schematic of the measurement system and (b) top view of the experimental facility (Fujiwara et al., 2004a).
Figure 10.11 Near-field imaging of SHG signals from a single Au nanoparticle.250 (a) Schematic of experimental setup (b) AFM image of an elliptical nanoparticle (c, d) near-field SHG signal mapping with emission detection polarized parallel and perpendicular to incident excitation. (Reprinted with permission from M. Zavelani-Rossi et al., Appl. Phys. Lett. 2008,92, 093119. Copyright 2008 American Institute of Physics.) (See color insert.)... Figure 10.11 Near-field imaging of SHG signals from a single Au nanoparticle.250 (a) Schematic of experimental setup (b) AFM image of an elliptical nanoparticle (c, d) near-field SHG signal mapping with emission detection polarized parallel and perpendicular to incident excitation. (Reprinted with permission from M. Zavelani-Rossi et al., Appl. Phys. Lett. 2008,92, 093119. Copyright 2008 American Institute of Physics.) (See color insert.)...
Schematic of experimental setup (a) reactor for film treatment (b) fluidized bed for treatment of powders... Schematic of experimental setup (a) reactor for film treatment (b) fluidized bed for treatment of powders...
Figure 9.2 Schematic of experimental setups for displacement chromatography, (a) Schematic employing a single 10-port valve, (b) Schematic employing a 6-port and a switching valve. Figure 9.2 Schematic of experimental setups for displacement chromatography, (a) Schematic employing a single 10-port valve, (b) Schematic employing a 6-port and a switching valve.
Figure 22. Edge toughness of LPS-SiC (EKasic T) compared to sintered AI2O3 and Si3N4 (a) flaking load against distance from edge, (b) schematic of experimental setup (Courtesy L.S.Sigl, ESK-Kempten/Germany). Figure 22. Edge toughness of LPS-SiC (EKasic T) compared to sintered AI2O3 and Si3N4 (a) flaking load against distance from edge, (b) schematic of experimental setup (Courtesy L.S.Sigl, ESK-Kempten/Germany).
Figure 5 Schematic of experimental setup used to determine (A) the extinction coefficient Px from normal-normal spectral transmittance and (B) the absorption coefficient Kx from normal-hemispherical spectral transmittance. Figure 5 Schematic of experimental setup used to determine (A) the extinction coefficient Px from normal-normal spectral transmittance and (B) the absorption coefficient Kx from normal-hemispherical spectral transmittance.
Lab-on-a-Chip Devices for Chemical Analysis, Fig. 9 (a) Schematic of experimental setup and (b) microchip layout. The device comprises two inlets, a meandering mixing channel, a detection chamber, and an outlet. The inlets are 400 pm wide, 800 pm deep, and... [Pg.1528]

Thermochromic Liquid Crystals for Particle Image Thermometry, Fig. 2 Schematic of experimental setup... [Pg.3274]

Fig. 6.6 Schematic of experimental setup. Reprinted from [Nguyen et al. (2009)]. Fig. 6.6 Schematic of experimental setup. Reprinted from [Nguyen et al. (2009)].
FIGURE 6.11 Schematic of experimental setup. 1. Stirred tank, 2. pump, 3. valve, 4. rotor flowmeter, 5. distributor, 6. packed rotator, 7. outlet, 8. valve, 9. rotor flow meter, 10. inlet. [Pg.113]

Schematic of experimental setup for positron annihilation lifetime spectroscopy. [Pg.245]

Fig. 5.7 Schematics of experimental setups for silicon nanowire growth ... Fig. 5.7 Schematics of experimental setups for silicon nanowire growth ...
Figure 4 Schematic of experimental setup. Inset is a reflected spectrum of FBG humidity sensor at room condition (25 °C, 60 %RH)... Figure 4 Schematic of experimental setup. Inset is a reflected spectrum of FBG humidity sensor at room condition (25 °C, 60 %RH)...
Figure 5. Schematics of experimental setups for film preparation under (a) flipping rotation and (b) conventional rotation. The black dashed line represents the axis of rotation. The axis is in the substrate plane for the flipping rotation, whereas the axis is perpendicular to the substrate plane for the conventional rotation. In the flipping rotation the incident flux angle a(t) Irom the target relative to the substrate normal (dash-dotted line) is a function of time. In the conventional rotation mode the ao is a constant value. lOP Publishing, Reproduced by permission of lOP publishing. From [44]. Figure 5. Schematics of experimental setups for film preparation under (a) flipping rotation and (b) conventional rotation. The black dashed line represents the axis of rotation. The axis is in the substrate plane for the flipping rotation, whereas the axis is perpendicular to the substrate plane for the conventional rotation. In the flipping rotation the incident flux angle a(t) Irom the target relative to the substrate normal (dash-dotted line) is a function of time. In the conventional rotation mode the ao is a constant value. lOP Publishing, Reproduced by permission of lOP publishing. From [44].
Figure 1 Schematic of experimental setup, (a) quartz microbalance (b) vacuum chamber (c) gas dosing system (d) pressure measurement system (e) vacuum jacket (f) thermal link, including heater and thermometer (g) oscillator circuit. Figure 1 Schematic of experimental setup, (a) quartz microbalance (b) vacuum chamber (c) gas dosing system (d) pressure measurement system (e) vacuum jacket (f) thermal link, including heater and thermometer (g) oscillator circuit.
Schematic of experimental setup for HGRP. Reprinted with permission from ref. 10 (Figure 1). Copyright (2000) American Chemical Society. [Pg.413]

See other pages where Schematic of experimental setup is mentioned: [Pg.307]    [Pg.216]    [Pg.420]    [Pg.323]    [Pg.444]   
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Experimental schematic

Experimental setups

Schematic Diagram of the Experimental Setup

Schematic diagram of experimental setup

Setup

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