Solution schematic representation

Figure 3.1. Main trends in the behaviour of mixed biopolymer solutions. Schematic representation of the four possible results obtained by mixing solutions of biopolymers a protein and a polysaccharide a protein and another protein a polysaccharide and another polysaccharide.

FigureBl.7.2. Schematic representations of alternative ionization methods to El and PI (a) fast-atom bombardment in which a beam of keV atoms desorbs solute from a matrix (b) matrix-assisted laser desorption ionization and (c) electrospray ionization.

Figure Bl.20.9. Schematic representation of DLVO-type forces measured between two mica surfaces in aqueous solutions of KNO3 or KCl at various concentrations. The inset reveals the existence of oscillatory and monotonic structural forces, of which the latter clearly depend on the salt concentration. Reproduced with pennission from [94].

Fig. 2. Schematic representation of relevant electrolyte transport through the renal tubule, depicting the osmolar gradient ia medullary iaterstitial fluid ia ywOj yW where represents active transport, —passive transport, hoth active and passive transport, and passive transport of H2O ia the presence of ADH, ia A, the cortex, and B, the medulla. An osmole equals a mole of solute divided by the number of ions formed per molecule of the solute. Thus one mole of sodium chloride is equivalent to two osmoles, ie, lAfNaCl = 2 Osm NaCl. ADH = antidiuretic hormone.

Figure 1 Schematic representation of an atomic model of a biomolecular solute surrounded by explicit water molecules.

Figure 2 Schematic representation of a biomolecular solute in a solvent environment that is taken into account implicitly.

Figure 3 Schematic representation of a mixed explicit-implicit solvent treatment. A small number of water molecules are included explicitly in the vicinity of the solute while the influence of the remaining bulk is taken into account implicitly.

Figure 9.18 Schematic representations of solution to the ammonia removal case study (a) with internal coaling, (b) with external cooling.

According to Eq. (4-62), when woTo < 1, T, is proportional to 1/Tc, whereas when woTc 1, Ti is proportional to Tc. When Tc = Wo, Tj has its minimum value. Figure 4-7 is a schematic representation of the relationship between T and Tc. The physical meaning of this relationship is that coupling between the spin system and the lattice is most efficient when the resonance frequency and the frequency of molecular motion are equal. Tc can be measured by studying the dependence of Ti on wq (by varying the field strength). For small molecules in solution Tc is commonly 10 to 10 s. 

Schematic representation of Ihe principal equilbiia in Giignord solutions, solvation of the various species has been omitted for clarity.

Figure 2.2 Schematic representation of an on-column interface. The eluent leaving the HPLC detector enters the valve and in the stand-hy position, leaves it to go to waste. When the valve is switched on, the eluent is pumped through the transfer line into the inlet of the on-column injector. The liquid floods the capillary wall, thus creating a layer that will retain the solutes. Evaporation occurs from the rear pait of the solvent so refocusing the chromatographic hand. At the end of the transfer, the valve is switched off, and the eluent again flows to waste.

Feed solution Liquid membrane Receiving solution Fig. 5-1. Schematic representation of a liquid membrane for chiral separation. 

Fig. 8.3 Schematic representation of the stress corrosion cracking mechanism of the pit (after Pickering and Swann ). (a) Tubular pits initiated at solute-rich slip step. The pits may, but need not necessarily, follow the slip plane once they are initiated, (b) Ductile tearing along a plane containing the tubular pits. The stress is increased across the plane because of the reduced cross section and the stress raising effect...

Fig. 19.39 Schematic representation of reactions during (a) controlled potential and (b) conventional corrosion tests in acidic chloride solutions. In (a) charge balance must be maintained by migration of Cl" ions, since the cathodic reaction occurs elsewhere at the counter-electrode. In (b) the anodic and cathodic sites are in close proximity, and charge balance is maintained without migration of Cl" ions from the bulk solution (after France and Greene )...

Figure 9.5 Schematic representation of a polarimeter. Plane-polarized light passes through a solution of optically active molecules, which rotate the plane of polarization.

Figure 7.10 Schematic representation of the apparatus for measuring osmotic pressure. The flow of solvent through the semipermeable membrane is followed by observing the movement of the meniscus of the flow indicator. The osmotic pressure II is the pressure that must be applied to the solution to prevent the flow.

Figure 35. Schematic representation of the reversible variation of volume associated with the electrochemical switching of polypyrrole. Changes in free volume are mainly due to two effects electrostatic repulsions between fixed positive charges and exchange of cations, anions, and solvent molecules between the polymer and the solution. (Reprinted from T. F. Otero, H.-J. Grande, and J. Rodriguez, J. Phys. Chem. 101, 3688, 1997, Figs. 1, 3,6, 7, 13. Copyright 1997. Reprinted with the permission of the American Chemical Society.)...

Fig. 2 Schematic representation of cellulose structures in solution Part A shows the fringed micellar structure. Parts B and C show possible chain conformations of celluloses of different DP. For high molecular weight cellulose, C, intra-molecular hydrogen bonding is possible...

Fio. 8. Schematic representation of the electrode-solution interface and the potential distribution in this zone. 

Fig. 15-1 Schematic representation of the change in water structure (water molecule orientation) due to the presence of a charged (hydrophilic) solute, (a) Pure water, (b) A solute forming strong bonds with water (dissolution favorable), (c) a solute forming weak bonds with water (dissolution unfavorable).

Fig. 2.14 Formulae of /5-peptides 81 and 82 forming stable 3,4-helical structures in aqueous solution and schematic representation of the position of the amino acid side-chains looking down the 3,4-helix axis [128, 165]...

Figure 2.4 Schematic representation of silicon hydrolysis from the zeolite framework in aqueous alkali hydroxide solution.

Fig. 5.9 Schematic representation of the energetic situation at the n-MoSe2/solution interface. (Reproduced from [140])...

Fig. 34.—Schematic representation of polymer molecules in dilute solution.

Figure 3 is a schematic representation of a typical CO electrode. A KCI/HCOJ containing electrolyte solution is trapped within a nylon mesh spacer layer whose pH is monitored by a contacting conventional glass pH electrode. A CO permeable membrane isolates the electrolyte layer from the analyte phase. Currently available... 

FIGURE 11.1 (a) Schematic representation of PLC of Heracleum moellendorfi fruit, crude extract (500-pl 2% solution), system Florisil/AcOEt + B plate preeluted with benzene (b) analytical HPLC of isolated fractions, system ClS/MeOH + HjO (6 4). Abbreviations B — bergaptene, I — imperatorin, Ph — phelopterin, X — xanthotoxin. (For details, see Waksmundzka-FIajnos, M. and Wawrzynowicz, T., 7. Planar Chromatogr., 5, 169-174, 1992.)... 

Fig. 12.3 Schematic representation of the charge flow due to polarization effects in the case of (A) acetate (ion loses about 0.022e) and (B) methylammonium (ion gains about 0.025e) ions in aqueous solution. Purple...

Figure 3.19 Schematic representation of surface alloy stability tests. White spheres denote adsorbed hydrogen, black spheres denote solute metal atoms, and gray spheres denote host metal atoms. Adapted from [Greeley and Nprskov, 2007] see this reference for more details.

Figure 17.17 Schematic representation of a single-compartment glucose/02 enzyme fuel cell built from carbon fiber electrodes modified with Os -containing polymers that incorporate glucose oxidase at the anode and bilirubin oxidase at the cathode. The inset shows power density versus cell potential curves for this fuel cell operating in a quiescent solution in air at pH 7.2, 0.14 M NaCl, 20 mM phosphate, and 15 mM glucose. Parts of this figure are reprinted with permission from Mano et al. [2003]. Copyright (2003) American Chemical Society.

Figure 17.19 A membianeless ethanol/02 enz3fme fuel cell. Alcohol dehydrogenase and aldehyde dehydrogenase catalyze a stepwise oxidation of ethanol to acetaldehyde and then to acetate, passing electrons to the anode via the mediator NAD+/NADH. At the carhon cathode, electrons are passed via the [Ru(2,2 -bipyridyl)3] and biUverdin/bilimbin couples to bilirubin oxidase, which catalyzes O2 reduction to H2O. (a) Schematic representation of the reactions occruring. (b) Power/cmrent response for the ceU operating in buffered solution at pH 7.15, containing 1 mM ethanol and 1 mM NAD. Panel (b) reprinted from Topcagic and Minteer [2006]. Copyright Elsevier, 2006.

FIG. 10 Schematic representation of the proposed surface model (a) the concentration and (b) the electrical potential profiles at the interface of the membrane and aqueous sample solution, x = 0 and 0 are the positions of ions in the planes of closest approach (outer Helmholtz planes) from the aqueous and membrane sides, respectively. (From Ref. 17.)... 

Fig. 1.15 A schematic representation of a polyacid solution including polyanions , anions of an added low molecular electrolyte O and positive counterions ...

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