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Cross-sectional diagram

Figure Bl.7.14. Schematic cross-sectional diagram of a quadnipole ion trap mass spectrometer. The distance between the two endcap electrodes is 2zq, while the radius of the ring electrode is (reproduced with pennission of Professor R March, Trent University, Peterborough, ON, Canada). Figure Bl.7.14. Schematic cross-sectional diagram of a quadnipole ion trap mass spectrometer. The distance between the two endcap electrodes is 2zq, while the radius of the ring electrode is (reproduced with pennission of Professor R March, Trent University, Peterborough, ON, Canada).
The sensation of colour that we experience arises from the interpretation by the brain of the signals that it receives via the optic nerve from the eye in response to stimulation by light. This section contains a brief description of the components of the eye and an outline of how each of these contributes to the mechanism by which we observe colours. Figure 2.2 shows a cross-section diagram of the eye, indicating some of the more important components. [Pg.15]

Fig. 4. I(V) characteristics of diodes under reverse bias Iox, Si02-passivated Ia.si H, a-Si H passivated the dashed line shows Ia.si H after heating at 500°C for hour. The inset shows a cross-sectional diagram of the diode. Fig. 4. I(V) characteristics of diodes under reverse bias Iox, Si02-passivated Ia.si H, a-Si H passivated the dashed line shows Ia.si H after heating at 500°C for hour. The inset shows a cross-sectional diagram of the diode.
Figure 1. Cross-sectional diagram of an expanding 2 1 layer silicate showing the octahedral layer, tetrahedral layer, and hydrated exchange cations in the interlayer. Figure 1. Cross-sectional diagram of an expanding 2 1 layer silicate showing the octahedral layer, tetrahedral layer, and hydrated exchange cations in the interlayer.
Figure 4.13. Cross-sectional diagram of a diffusion tube (courtesy Analytical Instrument Development). Figure 4.13. Cross-sectional diagram of a diffusion tube (courtesy Analytical Instrument Development).
Figure 17. Cross-sectional diagram of ESEM illustrating differential pressures at various sites along the column, culminating in a specimen chamber at relatively high pressures. [From E. Doehne and D.C. Stulik, Scanning Microscopy 2, (1990), 275-286.]... Figure 17. Cross-sectional diagram of ESEM illustrating differential pressures at various sites along the column, culminating in a specimen chamber at relatively high pressures. [From E. Doehne and D.C. Stulik, Scanning Microscopy 2, (1990), 275-286.]...
Figure 3.17 Cross-sectional diagram of a thin film rechargeable lithium battery based on the conductivity of lithium triflate in solid pol y W.v(mcthoxyethoxyethoxy )phosphazene]. Figure 3.17 Cross-sectional diagram of a thin film rechargeable lithium battery based on the conductivity of lithium triflate in solid pol y W.v(mcthoxyethoxyethoxy )phosphazene].
Fig. 10.1 Pictures for the different designs of SOFCs and the related cross-sectional diagrams (a) electrolyte-supporting planar cell, (b) anode-supported planar cell, (c) tubular cell, (d) segmented cell in-series design. Fig. 10.1 Pictures for the different designs of SOFCs and the related cross-sectional diagrams (a) electrolyte-supporting planar cell, (b) anode-supported planar cell, (c) tubular cell, (d) segmented cell in-series design.
Fig. 2.2 The cross-sectional diagram of human skin tissue... Fig. 2.2 The cross-sectional diagram of human skin tissue...
Figure 8.16 Cross-sectional diagram of a single-use disposable powder injection system highlighting the major components. When the actuator button is depressed, the driver gas (He) is released into the surrounding rupture chamber. At a specific pressure, the plastic membranes of the drug cassette burst and the drug particles are entrained in the gas flow, which is accelerated through the convergent-divergent nozzle. [From Hickey (2001). Reproduced with permission from Euromed Communications.]... Figure 8.16 Cross-sectional diagram of a single-use disposable powder injection system highlighting the major components. When the actuator button is depressed, the driver gas (He) is released into the surrounding rupture chamber. At a specific pressure, the plastic membranes of the drug cassette burst and the drug particles are entrained in the gas flow, which is accelerated through the convergent-divergent nozzle. [From Hickey (2001). Reproduced with permission from Euromed Communications.]...
A ring helix, (8), is characterized by divergence of alternate bonds (ai, a2 and bi, b2) as seen in the cross-sectional diagram. Since, in [2]-helices, = B it follows that for ring helices ... [Pg.56]

Fig. 3.12 An 8-channel-fixed bed reactor module (a) and a cross-sectional diagram of a reactor module (b). Fig. 3.12 An 8-channel-fixed bed reactor module (a) and a cross-sectional diagram of a reactor module (b).
Figure 9 The cross-sectional diagram of a typical HDI for a HDD system with aluminum substrate. Figure 9 The cross-sectional diagram of a typical HDI for a HDD system with aluminum substrate.
Figure 4 (a) Cross-sectional diagram of a silicon-based microcavity discharge device with an inverted square pyramid microcavity and (b) an SEM (scanning electron microscopy) image of a single microplasma device with 50 x 50 pm2 emitting aperture (Becker et al, 2006 reproduced with permission). [Pg.45]

A cross-sectional diagram of a resonant cavity magnetron. The magnetic field is perpendicular to the plane of the diagram. [Pg.596]

Figure 2.2 Cross-sectional diagram of the components used to couple two pieces of stainless steel tubing. Top Units before swaging. T, tubing to be joined B, male bolt F, female N, female nut. Bottom After swaging. The pressure of the bolt on the nut has forced the ferrule to seal the joint between the two ends of the tubing. Figure 2.2 Cross-sectional diagram of the components used to couple two pieces of stainless steel tubing. Top Units before swaging. T, tubing to be joined B, male bolt F, female N, female nut. Bottom After swaging. The pressure of the bolt on the nut has forced the ferrule to seal the joint between the two ends of the tubing.
Figure 2-3 Cross-sectional diagram of the cornea. Note that the epithelium is only approximately one-tenth the total comeal mass. Nevertheless, it can be considered a separate storage depot for certain lipophilic dmgs. Figure 2-3 Cross-sectional diagram of the cornea. Note that the epithelium is only approximately one-tenth the total comeal mass. Nevertheless, it can be considered a separate storage depot for certain lipophilic dmgs.
Figure 9-1. Cross-sectional diagram of an angle head rotor showing the distances from the axis of rotation to the top, middle, and bottom of the centrifuge tube. (Courtesy Spinco Division, Beckman Instruments, Inc., Palo Alto, Calif.)... Figure 9-1. Cross-sectional diagram of an angle head rotor showing the distances from the axis of rotation to the top, middle, and bottom of the centrifuge tube. (Courtesy Spinco Division, Beckman Instruments, Inc., Palo Alto, Calif.)...
Figure 4 (A) UV2000 fluorescent testing apparatus and (B) is a cross-sectional diagram of the test chamber before modification tor pharmaceutical photostability testing. Source. Courtesy of Atlas Material Testing Technology LLC. Figure 4 (A) UV2000 fluorescent testing apparatus and (B) is a cross-sectional diagram of the test chamber before modification tor pharmaceutical photostability testing. Source. Courtesy of Atlas Material Testing Technology LLC.
Figure 13 Light-Tron LT-120 series photostability testing device (A) as is and (B) in cross sectional diagram. Turntable ( 4), UV-A sensor ( 5), VIS sensor ( 6), turntable motor ( 7), VIS (21) and UV-a lamp (22). Source-. Courtesy of Nagano Science Equipment Mtg. Co. Ltd. Figure 13 Light-Tron LT-120 series photostability testing device (A) as is and (B) in cross sectional diagram. Turntable ( 4), UV-A sensor ( 5), VIS sensor ( 6), turntable motor ( 7), VIS (21) and UV-a lamp (22). Source-. Courtesy of Nagano Science Equipment Mtg. Co. Ltd.
FIGURE 23.9 Vertical cross-sectional diagram including 123 and 211 compounds in pseudoternary phase diagram. (From Osamura, K., et al., Z. Metllkd., 84, 408, 1991.)... [Pg.422]

Figure 3. Cross-sectional diagram of the optical system of the chlorophyll sensor showing the flash lamp and Litepac L, the blue filters FI, the sample cell SC, the red filters F2, and the photodetector PD. The transmission spectra of the blue filters (Corning 5-57, solid line and Corning 4-96, dashed line), the red interference filters (IF), and the blocking filter (Corning 2-58)... Figure 3. Cross-sectional diagram of the optical system of the chlorophyll sensor showing the flash lamp and Litepac L, the blue filters FI, the sample cell SC, the red filters F2, and the photodetector PD. The transmission spectra of the blue filters (Corning 5-57, solid line and Corning 4-96, dashed line), the red interference filters (IF), and the blocking filter (Corning 2-58)...
Fig. 7.15. Electrophoretic destaining apparatus (Richards and Gratzer 1968) cross sectional diagram of electrolytic destainer. Three gels are shown in the gel compartment (b) composed of a perspex (Incite) frame bounded by two sheets of Vyon porous plastic (d). This compartment rests in a holder made of two further perspex frames (a) joined along their bottom and sides. The gel compartment and the porous plastic are held in the holder by a fourth removable perspex frame (c). The holder fits tightly into a perspex tank (e) and thus separates the two buffer compartments (g), which are normally filled with 10% acetic acid. The potential is applied through two j in carbon rods (f) which are mounted in the tank through rubber grommets. Fig. 7.15. Electrophoretic destaining apparatus (Richards and Gratzer 1968) cross sectional diagram of electrolytic destainer. Three gels are shown in the gel compartment (b) composed of a perspex (Incite) frame bounded by two sheets of Vyon porous plastic (d). This compartment rests in a holder made of two further perspex frames (a) joined along their bottom and sides. The gel compartment and the porous plastic are held in the holder by a fourth removable perspex frame (c). The holder fits tightly into a perspex tank (e) and thus separates the two buffer compartments (g), which are normally filled with 10% acetic acid. The potential is applied through two j in carbon rods (f) which are mounted in the tank through rubber grommets.
See other pages where Cross-sectional diagram is mentioned: [Pg.1814]    [Pg.235]    [Pg.523]    [Pg.2214]    [Pg.91]    [Pg.29]    [Pg.148]    [Pg.235]    [Pg.260]    [Pg.326]    [Pg.270]    [Pg.132]    [Pg.64]    [Pg.1970]    [Pg.244]    [Pg.420]    [Pg.273]    [Pg.273]    [Pg.276]    [Pg.2457]    [Pg.608]   
See also in sourсe #XX -- [ Pg.359 ]



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