Dual schematic representation

Figure 1.8 A schematic representation of a typical resonant circuit for a dual H/ C probe. The capacitors A, B, C, and D perform various functions, such as symmetry and matching resonance.

Figure 6.1 Schematic representation of the dual pathway mechanism for the electrocatal3ftic oxidation of methanol to carhon dioxide.

Figure 13.8 (a) Schematic representation of the original dual-pathway mechanism proposed... 

Figure 6.9 Schematic representation of the dual reactor system proposed for hydrogen generation by giucose APR (adapted from Ref. [281]).

TT-system can easily be realized (see schematic representation on page 53). (Ni part of the double-dual system shown below ... 

Figure 3. Schematic representation of a dual cell used for FTMS.

Fig. 3. Schematic representation of the dual activation mechanisms of an ER by the AF-1 and AF-2 sites.

FIGURE 47 Schematic representation of the complex multifunctions enabled in a dual membrane bioreactor for hydridoma cell culturing (Integra Biosciences AG, Wallisellen, Switzerland). 

FIGURE 6 Schematic representation of an oxide catalyst with its functional compartments in various structural states for high (back) and low (front) chemical potentials of oxygen. The arrows and the question mark indicate the complex distribution of oxygen in its dual role as a reactant at the surface and as a constituent of the catalyst material in the bulk. Its abundance is controlled by the presence of reducing species in the gas phase leading to a dependence of the results of XRD structural analysis on the availability of reducing gas-phase species. For details and references, see the text. 

Figure 20. Schematic representation of the analytical protocol of the biosensor (a) Dual hybridization event of the sandwich hybridization assay, leading to the capture of the CdS-loaded CNT tags in the microwell (b) dissolution of the CdS tracer (c) stripping voltammetric detection of cadmium at a mercury-coated glassy carbon electrode. PI, DNA probe 1 T, DNA target P2, DNA probe 2. From reference 114.

Figure 26.10 A schematic representation of the meniscus shape and position of the three-phase contact line (solid/liquid/air) during immersion and emersion of a hydrophobic surface (e.g., TMS treated polymers) the dual arrows indicate which direction the beaker is moving, the small arrow on the plate indicates the direction the three-phase contact line is moving.

Figure 20 Schematic representation of the dependence of concentration on partial pressure illustrating predications of Henry s law and dual mode sorption theory.

Figure 11.6.4 (a) Schematic representation of a dual-electrode flow cell, b) Actual complete... 

Fig. 4.23. Combined absorption and fluorescence spectrometo device in a schematic representation. An automatic dual beam DMR 21-spectrometer and a single beam PMQII-photometer are used. The cell holder ZFM4 cornices both instruments.

Scheme 8 Schematic representation of the dual-emission sensing mechanism of the acridine chemosensor for nucleoside PPs...

FIGURE I5.I Schematic representation of a dual-chamber ICD. The generator is implanted in the pectoral region. The defibrillation lead (lower) is in the rightventricle, where it is fixed by a helix at the distal (far) end of the lead. The atrial lead (upper) is secured by flexible tines in the right atrial appendage. (Reproduced with permission of Medtronic, Inc.)... 

Figure 3.11 Schematic representation (vertical cut view) of a high-pressure reactor with dual ATR-FTIR probes. (Adapted from Ref [15].)...

Model Order Reduction (MOR), Fig. 1 Schematic representations of three dual networks for droplet traffic modeling (a) a loop, (b) a Y-junction with bypass channel, and (c) a ladder... 

Figure 1 Schematic representation of synthetic strategies toward AB dibiock copolymers (a) by sequential monomer addition, (b) by dual initiator, (c) by site transformation technique, and (d) by coupiing of m-functionai poiymers. i, initiator F, functionalization agent , active site.

FIGURE 20.4-6 Schematic representation of the dual-mode concept. The sorption <4>setved during the first exposure to the penetrant is often considerably different from that observed after the isotherm has settled at the highest pressure of measurement. The conditioning process associated with the first exposure to the penetrant is believed to be associated with redistribution of unrelaxed volume elements in the polymer. 

Figure 3.17 Schematic representation of the orbitrap mass spectrometer. It consists of a QMF and a dual LIT. The C trap pushes ions into the orbitrap mass analyzer which is installed in the ultrahigh vacuum region...

Experimental Arrangement. A schematic representation of a SAW sensing device is provided in Figure 66. This particular resonator was used by D Amico et al. [311] for the detection of hydrogen. It consists of a dual delay-line structure in which one of the propagation paths (Is) is coated with a thin palladium film to act as the sensing channel, while the other (/r) is uncoated and serves as a reference. 

FIGURE 1.54. Schematic representation of dual-rail transmission line for electroactive polymer films. The / is resistance for electron hopping, Rj is resistance for counterion transport Cp is the distributed Faradaic capacitance, and denotes the uncompensated solution resistance. 

FIGURE 1.91. Schematic representation of the dual-electrode ring-disk (RD) geometry and the overcoated RRDE experiment illustrating concentration profiles of oxidized and reduced sites under steady-state conditions. 

Fig. 11.17 Schematic representation of dual layer Fe/Cu monolith catalyst. (Used with permission [80].)...

Figure 4.8 Schematic representation for the concentration-dependent dual pathway for chain folding below the setting temperature T. Reprinted with permission from [24]. Copyright 1970 American Chemical Society.

Fig. 15.3 Design of the dual drag-eluting stent. From left to right schematic representation of the dual drug-eluting stent, representative optical microscopy image of one representative strut cross section, representative electron micrograph...

Fig. 3 Schematic representation of (A) the top view of a double-barrel pipet and (B) the dual-liquid/liquid interface supported at a double-barrel pipet, and SEM images of the nanometersized double-barrel pipets with (C) i =115nm, d = 29nm and (D) il=65nm, d=36nm. Reprinted with permission from ref 34. Copyright 2006 American Chemical Society.

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