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Schematic of experimental

Fig. 1 Schematic of experimental setup used for TOFD measurements. Fig. 1 Schematic of experimental setup used for TOFD measurements.
Fig. 6.11. The schematics of experimental set-up to study emission of atomic oxygen. 1 — sensor of oxygen atoms 2 samples of reduced silver 3 shutter 4 weights to brake membranes 5 platinum filament to calibrate sensor against the concentration of oxygen atoms. Fig. 6.11. The schematics of experimental set-up to study emission of atomic oxygen. 1 — sensor of oxygen atoms 2 samples of reduced silver 3 shutter 4 weights to brake membranes 5 platinum filament to calibrate sensor against the concentration of oxygen atoms.
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 4.12 Schematic of experimental data for PCO reaction of toluene in a PCO reactor. Figure 4.12 Schematic of experimental data for PCO reaction of toluene in a PCO reactor.
Figure 3.49 Schematic of experimental set-up fora scanning mass spectrometer-assisted catalyst screening device [80] (by courtesy of AlChE). Figure 3.49 Schematic of experimental set-up fora scanning mass spectrometer-assisted catalyst screening device [80] (by courtesy of AlChE).
Figure 15 An example of PIV/LIF/SIT taken images (a) schematic of experimental conditions and ranges (b) typical PIV image showing illuminated tracer particles around the two bubbles (c) typical shadow images of the two bubbles at three instants (Tokuhiro et al, 1999). Figure 15 An example of PIV/LIF/SIT taken images (a) schematic of experimental conditions and ranges (b) typical PIV image showing illuminated tracer particles around the two bubbles (c) typical shadow images of the two bubbles at three instants (Tokuhiro et al, 1999).
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.)...
Figure 2. Schematics of experimental letups for three laser spectroscopic probe... Figure 2. Schematics of experimental letups for three laser spectroscopic probe...
Figure 1. Schematic of experimental apparatus for metal sulfide (1) reaction tube (2) electric furnace (3) metal sulfide (4) quartz wool (5) trap (6) cold bath (7) sampling tube (8) flow meter (9) trap (10) vacuum detector (11) trap (12)... Figure 1. Schematic of experimental apparatus for metal sulfide (1) reaction tube (2) electric furnace (3) metal sulfide (4) quartz wool (5) trap (6) cold bath (7) sampling tube (8) flow meter (9) trap (10) vacuum detector (11) trap (12)...
Figure 5. Schematic of experimental apparatus for molten lead (1) gas chamber (2) circulation pump (3) flow meter (4) pressure gauge (5) sampling tube (6) blowing nozzle (7) quartz tube (8) reaction tube (9) electric furnace (10) electric furnace (11) water jacket (12) thermocouple (13) thermocouple (14) silicon stopper. Figure 5. Schematic of experimental apparatus for molten lead (1) gas chamber (2) circulation pump (3) flow meter (4) pressure gauge (5) sampling tube (6) blowing nozzle (7) quartz tube (8) reaction tube (9) electric furnace (10) electric furnace (11) water jacket (12) thermocouple (13) thermocouple (14) silicon stopper.
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 2.7 Schematic of experimental set-up. Be sure that the inserted glass tubing is above the surface of liquid in the test tube as shown. Use a clamp and ring stand to secure the test tube in place. Heed cautionary note above. Adapted from Steve Marsder s Chemistry Resources for Students and Teacher.16... Figure 2.7 Schematic of experimental set-up. Be sure that the inserted glass tubing is above the surface of liquid in the test tube as shown. Use a clamp and ring stand to secure the test tube in place. Heed cautionary note above. Adapted from Steve Marsder s Chemistry Resources for Students and Teacher.16...
Figure 1. Schematic of experimental Apparatus for the cracking of cumene. Figure 1. Schematic of experimental Apparatus for the cracking of cumene.
Figure 4 (a) Schematic of experimental design of detecting single-head myosin catalysis using a fluorescent substrate. The laser excitation is in TIR geometry. The Cy5-label on the enzyme helps to identify the location of individual enzymes. [Pg.759]

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 I. Schematic of experimental apparatus for electrolysis stack testing... Figure I. Schematic of experimental apparatus for electrolysis stack testing...
Fig. 4.22. (a) Schematic of experimental set-up for microalbuminuria determination. (b) Microchip layout with inlets for AB 580 (1) and HSA (2), mixing channel (3), detection chamber (4), outlet (5), and orthogonal detection point (6) (Prom [35] - Reproduced by permission of The Royal Society of Chemistry)... [Pg.128]

Fig. 11 Schematic of experimental protocol for analysis of organic contaminants... [Pg.370]

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 9.10 An electro-optic phase modulator (a) schematic of experimental arrangement (b) output power for a sinusoidally varying voltage... Figure 9.10 An electro-optic phase modulator (a) schematic of experimental arrangement (b) output power for a sinusoidally varying voltage...
Fig. 7.5 Top Schematic of experimental device during the EHD lithography process under a laterally heterogeneous electric field, (a) A structured upper plate creates a heterogeneous force field focusing the instability towards the protruding structures (b). In (c) a positive replica of the master pattern is transferred into the polymer. In unstructured regions, the film remains stable on a much longer lime scale. Bottom High fidelity EHD lithography showing the robustness of pattern replication with respect to the parameters of the electrode... Fig. 7.5 Top Schematic of experimental device during the EHD lithography process under a laterally heterogeneous electric field, (a) A structured upper plate creates a heterogeneous force field focusing the instability towards the protruding structures (b). In (c) a positive replica of the master pattern is transferred into the polymer. In unstructured regions, the film remains stable on a much longer lime scale. Bottom High fidelity EHD lithography showing the robustness of pattern replication with respect to the parameters of the electrode...
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]

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