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Schematic diagram representation

Fig. 23. Schematic diagram of the 4-roll mill apparatus. Schematic representation of the flow field within the mill illustrating the deformation of a fluid element [35]... Fig. 23. Schematic diagram of the 4-roll mill apparatus. Schematic representation of the flow field within the mill illustrating the deformation of a fluid element [35]...
Figure 12.14 (Left) Schematic representation of tandemly repeated zinc finger motif with their tetrahedrally coordinated Zn2+ ions. Conserved amino acids are labelled, and the most probable DNA-binding side chains are indicated by balls (from Klug and Rhodes, 1988). (Right) A ribbon diagram of a single zinc finger motif in a ribbon diagram representation. (From Voet and Voet, 2004. Reproduced with permission from John Wiley Sons., Inc.)... Figure 12.14 (Left) Schematic representation of tandemly repeated zinc finger motif with their tetrahedrally coordinated Zn2+ ions. Conserved amino acids are labelled, and the most probable DNA-binding side chains are indicated by balls (from Klug and Rhodes, 1988). (Right) A ribbon diagram of a single zinc finger motif in a ribbon diagram representation. (From Voet and Voet, 2004. Reproduced with permission from John Wiley Sons., Inc.)...
Figure 4.2 — (A) Schematic diagram of an ammonia-N-sensitive probe based on an Ir-MOS capacitor. (Reproduced from [20] with permission of the American Chemical Society). (B) Pneumato-amperometric flow-through cell (a) upper Plexiglas part (b) metallized Gore-Tec membrane (c) auxiliary Gore-Tec membrane (d) polyethylene spacer (e) bottom Plexiglas part (/) carrier stream inlet (g) carrier stream outlet. (C) Schematic representation of the pneumato-amperometric process. The volatile species Y in the carrier stream diffuses through the membrane pores to the porous electrode surface in the electrochemical cell and is oxidized or reduced. (Reproduced from [21] with permission of the American Chemical Society). Figure 4.2 — (A) Schematic diagram of an ammonia-N-sensitive probe based on an Ir-MOS capacitor. (Reproduced from [20] with permission of the American Chemical Society). (B) Pneumato-amperometric flow-through cell (a) upper Plexiglas part (b) metallized Gore-Tec membrane (c) auxiliary Gore-Tec membrane (d) polyethylene spacer (e) bottom Plexiglas part (/) carrier stream inlet (g) carrier stream outlet. (C) Schematic representation of the pneumato-amperometric process. The volatile species Y in the carrier stream diffuses through the membrane pores to the porous electrode surface in the electrochemical cell and is oxidized or reduced. (Reproduced from [21] with permission of the American Chemical Society).
Fig. 12 (a) Schematic diagram of single molecule Cgo based electromechanical amplifier, (b) Schematic representation of the on/off states. (Reprinted with permission from [100])... [Pg.139]

Figure 8.40 Schematic diagram of an injection molding item with its projected area and its lay-flat representation. Figure 8.40 Schematic diagram of an injection molding item with its projected area and its lay-flat representation.
FIGURE 7.1 (a) The YB structures and their mixing diagram leading to the states of the H—H bond, (b) A Schematic MO representation of the first singlet excited state and its correspondence to the YB representation. [Pg.195]

Figure 8.3 Schematic diagrams of the three main categories of transdermal delivery system. It should be noted that these representations of the patches greatly exaggerate their real thicknesses, which are in fact similar to that of a normal Band-Aid... Figure 8.3 Schematic diagrams of the three main categories of transdermal delivery system. It should be noted that these representations of the patches greatly exaggerate their real thicknesses, which are in fact similar to that of a normal Band-Aid...
Figure 1-2. Schematic diagrammatic representation of the E correction (Brandow skeletons). The horizontal lines represent the denominators, while the vertical bar separates the monomers A and B. The two-electron integral corresponding to the dotted interaction line is a Coulomb integral. The dashed interaction lines represent antisymmetric two-electron integrals of the monomers. Diagram (a) is the intermolecular perturbation theory form of the MP5 contribution s, diagram (d) of qQ(/7), while (b) and (c) are combinations of 7s T and E (I)... Figure 1-2. Schematic diagrammatic representation of the E correction (Brandow skeletons). The horizontal lines represent the denominators, while the vertical bar separates the monomers A and B. The two-electron integral corresponding to the dotted interaction line is a Coulomb integral. The dashed interaction lines represent antisymmetric two-electron integrals of the monomers. Diagram (a) is the intermolecular perturbation theory form of the MP5 contribution s, diagram (d) of qQ(/7), while (b) and (c) are combinations of 7s T and E (I)...
Each representation of a protein or nucleic acid conveys to the viewer different aspects of its structure line drawings give the bones, space-filling models the flesh, and schematic diagrams the gestalt of the design. No single representation of a protein or nucleic acid is adequate for all purposes, but the combination of several is more powerful than the total of all taken independently. [Pg.157]

Fig. 15.1. Schematic representation of amyloid fibrils revealed by total internal reflection fluorescence microscopy, (a) The penetration depth of the evanescent field formed by the total internal reflection of laser light is 150nm for a laser light at 455 nm, so only amyloid fibrils lying parallel to the slide glass surface were observed. (b) Schematic diagram of a prism-type TIRFM system on an inverted microscope. ISIT image-intensifier-coupled silicone intensified target camera, CCD charge-coupled device camera... Fig. 15.1. Schematic representation of amyloid fibrils revealed by total internal reflection fluorescence microscopy, (a) The penetration depth of the evanescent field formed by the total internal reflection of laser light is 150nm for a laser light at 455 nm, so only amyloid fibrils lying parallel to the slide glass surface were observed. (b) Schematic diagram of a prism-type TIRFM system on an inverted microscope. ISIT image-intensifier-coupled silicone intensified target camera, CCD charge-coupled device camera...
Fig. 5. Schematic diagram of an eight-channel multiplexed electrospray source. At the current representation, only spray 1 can pass through the sampling rotor to the mass analyzer, whereas sprays 2-8 are blocked. Reprinted with permission from Micromass, UK... Fig. 5. Schematic diagram of an eight-channel multiplexed electrospray source. At the current representation, only spray 1 can pass through the sampling rotor to the mass analyzer, whereas sprays 2-8 are blocked. Reprinted with permission from Micromass, UK...
Fig. 4. Schematic (a) representation of excimer and exciplex formation in a dendrimer and (b) energy level diagram showing the three types of emissions that can result. Fig. 4. Schematic (a) representation of excimer and exciplex formation in a dendrimer and (b) energy level diagram showing the three types of emissions that can result.
The arrow represents the electron transfer excitation from the HOMO of the donor to the LUMO of the acceptor, iodine. (B) Schematic diagram of the back electron transfer process which leaves the molecular iodine electronically excited. (C) Pictorial representation of the HOMO in benzene and the LUMO of iodine. Adapted from Ref [55]. [Pg.3047]

Figure 20-3 Schematic diagram of a neuron. Representation of the variety of branching found in dendrites. Figure 20-3 Schematic diagram of a neuron. Representation of the variety of branching found in dendrites.
Fig. 3 Schematic diagram of the canonical MOs of benzene, phenide anion and phenylacetylene. The highest occupied molecular orbital (HOMO) and three lower ones HOMO-1, HOMO-2 and HOMO-3 are shown along with their symmetry representations... Fig. 3 Schematic diagram of the canonical MOs of benzene, phenide anion and phenylacetylene. The highest occupied molecular orbital (HOMO) and three lower ones HOMO-1, HOMO-2 and HOMO-3 are shown along with their symmetry representations...
Fig. 8.12. Nanoelectronic devices (a) Schematic diagram [163] for a carbon NT-FET. Vsd, source-drain voltage Vg, gate voltage. Reproduced from ref [163], with permission, (b) Scanning tunneling microscope (STM) picture of a SWNT field-effect transistor made using the design of (a) the aluminum strip is overcoated with aluminum oxide, (c) Image and overlaying schematic representation for the effect of electrical pulses in removing... Fig. 8.12. Nanoelectronic devices (a) Schematic diagram [163] for a carbon NT-FET. Vsd, source-drain voltage Vg, gate voltage. Reproduced from ref [163], with permission, (b) Scanning tunneling microscope (STM) picture of a SWNT field-effect transistor made using the design of (a) the aluminum strip is overcoated with aluminum oxide, (c) Image and overlaying schematic representation for the effect of electrical pulses in removing...
Scheme 2 Schematic representation of a hexopyranoses (a) and a 1 —>6 linked disaccharide (b) showing the uj torsion angle. Schematic diagram of the gt, tg, and gg staggered conformers around the C5-C6 bond. Scheme 2 Schematic representation of a hexopyranoses (a) and a 1 —>6 linked disaccharide (b) showing the uj torsion angle. Schematic diagram of the gt, tg, and gg staggered conformers around the C5-C6 bond.
FIGURE 7.11 Structure of Cu-methanobactin from M. trichosporium. (a) Schematic diagram, (b) Ball-and-stick representation of crystal structure. The copper ion is shown as a brown sphere. (From Balasubramanian Rosenzweig, 2008. Copyright 2008, American Chemical Society.)... [Pg.145]

Fig. 2.1 A schematic diagram of a carbon nanotube based electronic device in the ball-and-stick representation... Fig. 2.1 A schematic diagram of a carbon nanotube based electronic device in the ball-and-stick representation...
Fig. 6.5 Schematic diagram of a conductivity cell (a) and its impedance representation as an equivalent circuit (b). Capacitances Ci and C2 are at the electrode I solution... Fig. 6.5 Schematic diagram of a conductivity cell (a) and its impedance representation as an equivalent circuit (b). Capacitances Ci and C2 are at the electrode I solution...
Figure 2-4. A schematic diagram of die relative timing systems between laser, x-ray and sample photo-conversion hfetime. The nature of steady-state, pseudo-steady-state (in its simplest form) and stroboscopic pump-probe mediods are illustrated. The absolute timing for each method is on a separate scale die entire experiment is shown for die steady-state mediods the pseudo-steady-state representation shows up to the beginnings of die first data-collection frame the stroboscopic representation illustrates a regular pattern that occurs diroughout the experiment. Stroboscopic pseudo-steady-state methods are not represented here per se, but they essentially represent a combination of the basic pseudo-steady-state and stroboscopic methods shown here... Figure 2-4. A schematic diagram of die relative timing systems between laser, x-ray and sample photo-conversion hfetime. The nature of steady-state, pseudo-steady-state (in its simplest form) and stroboscopic pump-probe mediods are illustrated. The absolute timing for each method is on a separate scale die entire experiment is shown for die steady-state mediods the pseudo-steady-state representation shows up to the beginnings of die first data-collection frame the stroboscopic representation illustrates a regular pattern that occurs diroughout the experiment. Stroboscopic pseudo-steady-state methods are not represented here per se, but they essentially represent a combination of the basic pseudo-steady-state and stroboscopic methods shown here...
Figure 7.4 Antibody Representations, (a) X-ray crystal structure, (b) Schematic diagram drawn from X-ray crystal structure illustrating the conserved structural features of all antibodies (illustrations a) and b) from Voet, Voet Pratt, 1999 [Wiley], Figs. 7-33 and 7-34 respectively). Figure 7.4 Antibody Representations, (a) X-ray crystal structure, (b) Schematic diagram drawn from X-ray crystal structure illustrating the conserved structural features of all antibodies (illustrations a) and b) from Voet, Voet Pratt, 1999 [Wiley], Figs. 7-33 and 7-34 respectively).
Fig. 23. Schematic diagrams of a possible density of states in a-Si H (left-hand side) and a schematic representation of the spatial variation of localized electronic states in a-Si H (right-hand side). [Reprinted by permission of the publisher from Electron spin resonance studies of amorphous silicon, by D. K. Biegelsen, Proceedings of the Electron Resonance Society Symposium, Vol. 3, pp. 85-94. Copyright 1981 by Elsevier Science Publishing Co., Inc.]... Fig. 23. Schematic diagrams of a possible density of states in a-Si H (left-hand side) and a schematic representation of the spatial variation of localized electronic states in a-Si H (right-hand side). [Reprinted by permission of the publisher from Electron spin resonance studies of amorphous silicon, by D. K. Biegelsen, Proceedings of the Electron Resonance Society Symposium, Vol. 3, pp. 85-94. Copyright 1981 by Elsevier Science Publishing Co., Inc.]...
Figure 3.8 (a) Schematic diagram of the top-down approach for synthesizing GQDs. Reproduced from Ref [116] with permission from RSC. (b) Representation scheme of oxidation cutting of CF into GQDs and proposed mechanism. Reproduced from Ref [47] with permission from ACS. [Pg.175]

Figure 2 Schematic diagram of a DGT sampler designed for water quality monitoring and schematic representation of the free concentration profile of ionic species in the sampler when in contact with an aqueous solution. DBL is the diffusive boundary layer. (Reprinted with permission from Zhang H and Davison W (1995) Performance characteristics of diffusion gradients in thin films of the in situ measurement of trace metals in aqueous solution. Anaiytical Chemistry 67 3391-3400 American Chemical Society.)... Figure 2 Schematic diagram of a DGT sampler designed for water quality monitoring and schematic representation of the free concentration profile of ionic species in the sampler when in contact with an aqueous solution. DBL is the diffusive boundary layer. (Reprinted with permission from Zhang H and Davison W (1995) Performance characteristics of diffusion gradients in thin films of the in situ measurement of trace metals in aqueous solution. Anaiytical Chemistry 67 3391-3400 American Chemical Society.)...
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