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Schematic representation of surface

Figure 14.2 Schematic representation of surface reactions in the (a) low- and (b) high-current states, respectively. Figure 14.2 Schematic representation of surface reactions in the (a) low- and (b) high-current states, respectively.
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 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 24 The n-A isotherms for mixtures of AA with AV2+ by a molar fraction of (a) 0.10, (b) 0.188, and (c) 0.50 at pH 63 and 18°C. The inset shows the schematic representation of surface monolayers during compression processes (C) -> (B) -> (A). Hie circle and rectangle in the inset represent TFPB" and 4,4 -bipyridinium group of AV2+, respectively. Figure 24 The n-A isotherms for mixtures of AA with AV2+ by a molar fraction of (a) 0.10, (b) 0.188, and (c) 0.50 at pH 63 and 18°C. The inset shows the schematic representation of surface monolayers during compression processes (C) -> (B) -> (A). Hie circle and rectangle in the inset represent TFPB" and 4,4 -bipyridinium group of AV2+, respectively.
Schematic representation of surface precipitation on hydrous ferric oxide (Fe(OH)3(s))... Schematic representation of surface precipitation on hydrous ferric oxide (Fe(OH)3(s))...
Fig. 2 Schematic representation of surface-anchored polymers in brush (left) and mushroom (middle) conformations in good solvents. Also shown is the conformation of a surface-tethered polymer under poor solvent conditions (right)... Fig. 2 Schematic representation of surface-anchored polymers in brush (left) and mushroom (middle) conformations in good solvents. Also shown is the conformation of a surface-tethered polymer under poor solvent conditions (right)...
Figure 2.27 Schematic representation of surface and bulk atoms in a condensed phase. From W. D. Kingery, H. K. Bowen, and D. R. Uhhnann, Introduction to Ceramics. Copyright 1976 by John Wiley Sons, Inc. This material is used by permission of John Wiley Sons, Inc. Figure 2.27 Schematic representation of surface and bulk atoms in a condensed phase. From W. D. Kingery, H. K. Bowen, and D. R. Uhhnann, Introduction to Ceramics. Copyright 1976 by John Wiley Sons, Inc. This material is used by permission of John Wiley Sons, Inc.
Fig. 4. Schematic representation of surface currents in the north Atlantic Ocean and stations where surface waters were collected. Areas I to V indicate regions with common temperature, salinity and nutrient characteristics. Fig. 4. Schematic representation of surface currents in the north Atlantic Ocean and stations where surface waters were collected. Areas I to V indicate regions with common temperature, salinity and nutrient characteristics.
Fig. 17. Schematic representation of surface chain reaction scheme for isobutane conversion on solid acid catalysts (99). Fig. 17. Schematic representation of surface chain reaction scheme for isobutane conversion on solid acid catalysts (99).
Fig. 4. Schematic representation of surface diffraction from dielectric pattern, based on total internal reflection (TIR) and attenuated total reflection (ATR) coupling geometries, respectively. Fig. 4. Schematic representation of surface diffraction from dielectric pattern, based on total internal reflection (TIR) and attenuated total reflection (ATR) coupling geometries, respectively.
Fig. 6. The schematic representation of surface patterning, site-specific polymerization, and site-specific immobilization of microparticles. Fig. 6. The schematic representation of surface patterning, site-specific polymerization, and site-specific immobilization of microparticles.
Figure 2. Schematic representation of surface transport processes (A) unrolling-carpet mechanism (B) transport by defect diffusion. Figure 2. Schematic representation of surface transport processes (A) unrolling-carpet mechanism (B) transport by defect diffusion.
Fig. 10 Schematic representation of surface dangling bonds of diamond and passivation by hydrogen. ... Fig. 10 Schematic representation of surface dangling bonds of diamond and passivation by hydrogen. ...
Figure 13.28. Schematic representation of surface precipitation on hydrous ferric oxide, Fe(OH)3(s). (a) At low surface coverage with Me, surface complex formation dominates. Instead of the usual short-hand notation (=Fe—OH + Me " 5= FeOMe" + H ), we use one that shows the presence of Fe(0H)3(s). (b) With progressive surface coverage, surface precipitation may occur. The surface precipitate is looked at as a solid solution of Fe(OH)3(s) and Me(0H)2(s) some isomorphic substitution of Me(II) for Fe(III) occurs. This model has been proposed by Farley et al. (1985). Figure 13.28. Schematic representation of surface precipitation on hydrous ferric oxide, Fe(OH)3(s). (a) At low surface coverage with Me, surface complex formation dominates. Instead of the usual short-hand notation (=Fe—OH + Me " 5= FeOMe" + H ), we use one that shows the presence of Fe(0H)3(s). (b) With progressive surface coverage, surface precipitation may occur. The surface precipitate is looked at as a solid solution of Fe(OH)3(s) and Me(0H)2(s) some isomorphic substitution of Me(II) for Fe(III) occurs. This model has been proposed by Farley et al. (1985).
Schematic representation of surface textural changes and suggested reaction model proposed to explain observations for the dehydrations of KA1(S04)2.12H20 and of KCr(S04)2.12H20... Schematic representation of surface textural changes and suggested reaction model proposed to explain observations for the dehydrations of KA1(S04)2.12H20 and of KCr(S04)2.12H20...
Figure 2. Schematic representation of surface complexes formed between inorganic ions and hydroxyl groups of an oxide surface. Modified fi om Hayes (78 with permission. Figure 2. Schematic representation of surface complexes formed between inorganic ions and hydroxyl groups of an oxide surface. Modified fi om Hayes (78 with permission.
Fig.5. Schematic representation of Surface Plasmon Resonance (SPR) method for detecting gases or fluids. The minimum in the reflectivity occurs due to plasmon absorption. [Pg.480]

Figure 17.29. Schematic representation of surface modification using a UV-curable surfactant... Figure 17.29. Schematic representation of surface modification using a UV-curable surfactant...
Figure 17.30. Schematic representation of surface modification of a lacquer film through migration of the surfactant to the film-air interface, followed by UV curing... Figure 17.30. Schematic representation of surface modification of a lacquer film through migration of the surfactant to the film-air interface, followed by UV curing...
FIGURE 7.12 Schematic representation of surface regions for a plastic substrate. [Pg.431]

Fig. 3 Schematic representation of surface imprinting of a protein 1, protein immobilization on the surface 2, surface polymerization 3, removal of initial surface and template 4, protein rebinding. Fig. 3 Schematic representation of surface imprinting of a protein 1, protein immobilization on the surface 2, surface polymerization 3, removal of initial surface and template 4, protein rebinding.
The reaction step which is autocatalytic in CO is the regeneration of the surface phase necessary to dissociate O2. Two vacant sites generate four vacant sites. Several autocatalytic reaction step>s are coupled in the CO oxidation reaction ( is schematic representation of surface vacancy). [Pg.343]

Figure 12. Schematic representation of surface damage in the preparation of solid section. Figure 12. Schematic representation of surface damage in the preparation of solid section.
Fig. 4.2 Schematic representation of surface effect in the case of a nanoparticle (left) and of... Fig. 4.2 Schematic representation of surface effect in the case of a nanoparticle (left) and of...
Fig. 38. Schematic representation of surfaces exhibiting one-atom step height configuration, multiple-height step structure, and hill-and-valley configuration consisting of large facet planes. Reconstruction from one type to another may occur on adsorption and/or heating... Fig. 38. Schematic representation of surfaces exhibiting one-atom step height configuration, multiple-height step structure, and hill-and-valley configuration consisting of large facet planes. Reconstruction from one type to another may occur on adsorption and/or heating...
FIGURE 20.30 (a) Schematic representation of surface-induced, on-site polycondensation of a Jt-conjugated polymer and (b) aromatic amine and aromatic aldehyde units used for on-site polycondensation. (Reprinted with permission from Liu, Y.F., Krug, K., Lee, Y.L., Self-organization of two-dimensional poly(3-hexylthiophene) crystals on Au(lll) surfaces. Nanoscale, 5,7936-7941,2013. Copyright 2013 American Chemical Society.)... [Pg.731]

Figure 4.11 Schematic representations of surface defects that are potential adsorption sites for catalysis. Individual atom sites are represented as cubes. Figure 4.11 Schematic representations of surface defects that are potential adsorption sites for catalysis. Individual atom sites are represented as cubes.
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Schematic representation

Schematic representation of potential energy surface

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