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Schematic representation of structures

Figure 10 (a) Schematic representation of structural modulations showing repeated shortening and widening of Bi-Bi distances, (b) Modulations in Bi-Bi separation in adjacent layers, indicating a sinusoidal variation. [Pg.584]

Figure 8.1 Schematic representation of structure of the flexible disordered caseins at a planar hydrophobic interface (a) asi-casein (b) p-casein. The solid bars denote hydrophobic regions of the molecules they do not imply rigidity. Reproduced from Home (1998) with permission. Figure 8.1 Schematic representation of structure of the flexible disordered caseins at a planar hydrophobic interface (a) asi-casein (b) p-casein. The solid bars denote hydrophobic regions of the molecules they do not imply rigidity. Reproduced from Home (1998) with permission.
Figure 1.2. Schematic representation of structural groups and connecting bridges in bituminous coal according to Wiser.8b... Figure 1.2. Schematic representation of structural groups and connecting bridges in bituminous coal according to Wiser.8b...
Figure 4. Schematic representation of structure of mono-layers... Figure 4. Schematic representation of structure of mono-layers...
Fig. 25. Schematic representation of structural relationship between layers of MM (dotted), CP (banded) and CaCC>3 (block-shaped)... Fig. 25. Schematic representation of structural relationship between layers of MM (dotted), CP (banded) and CaCC>3 (block-shaped)...
Figure 10. Schematic representation of structural change between three forms of... Figure 10. Schematic representation of structural change between three forms of...
Fig. 36. Photoelectron spectra and schematic representations of structures of various vanadium oxides [98, 173]. For comparison a computed density of states [172] is shown. Fig. 36. Photoelectron spectra and schematic representations of structures of various vanadium oxides [98, 173]. For comparison a computed density of states [172] is shown.
Figure 8.1.2 Schematic Representation of Structure 8.5a in a Figure-eight Conformation... Figure 8.1.2 Schematic Representation of Structure 8.5a in a Figure-eight Conformation...
Figure 13. Schematic representation of structures of (a) MV-K4Nb60n and (b) MV/K-K4Nb60i7. Reprinted with permission from T. Nakato, K. Kuroda and C. Kato, Chem. Mater. 1992, 4, 128. Copyright 1992 American Chemical Society. Figure 13. Schematic representation of structures of (a) MV-K4Nb60n and (b) MV/K-K4Nb60i7. Reprinted with permission from T. Nakato, K. Kuroda and C. Kato, Chem. Mater. 1992, 4, 128. Copyright 1992 American Chemical Society.
Schematic representation of structures within the hepatic lobule. H = hepatocyte, BC = bile canaliculus, KC = Kupffer cell, EC = endothelial cell, N = nerve fiber, F = reticulin fibers, S = sinusoid, D = space of Disse, X = gap between sinusoid lining cells, and RBC = red blood cell. Schematic representation of structures within the hepatic lobule. H = hepatocyte, BC = bile canaliculus, KC = Kupffer cell, EC = endothelial cell, N = nerve fiber, F = reticulin fibers, S = sinusoid, D = space of Disse, X = gap between sinusoid lining cells, and RBC = red blood cell.
Fig. 6. Histogram of number of structures vs. target function energy calculated for neocarzinostatin using 4,000 initial structures, and schematic representation of probable distribution of local minima. (A) Result of first round of SA (see Fig. 4), (B) result of second round of SA, (C) schematic representation of structure distribution of final result with expanded horizontal scale. Arrow indicates a probable cut-off target function value for final structure ensemble. Fig. 6. Histogram of number of structures vs. target function energy calculated for neocarzinostatin using 4,000 initial structures, and schematic representation of probable distribution of local minima. (A) Result of first round of SA (see Fig. 4), (B) result of second round of SA, (C) schematic representation of structure distribution of final result with expanded horizontal scale. Arrow indicates a probable cut-off target function value for final structure ensemble.
Figure 12.9 Schematic representation of structural changes of PTCDA on ordering in the herringbone phase [35]. Left disordered low temperature phase. Right herringbone phase. Figure 12.9 Schematic representation of structural changes of PTCDA on ordering in the herringbone phase [35]. Left disordered low temperature phase. Right herringbone phase.
Fig. 18 Schematic representation of structural change of the iron-loaded mPDMS elastomer under compression... Fig. 18 Schematic representation of structural change of the iron-loaded mPDMS elastomer under compression...
Fig. 1. Schematic representation of structure, crystal symmetry and energetic distribution of electronic d-states derived from the transition metal (M-d) in semiconducting dichalcogenides of Group TV, VI and VIII and semimetallic compounds of Group V... Fig. 1. Schematic representation of structure, crystal symmetry and energetic distribution of electronic d-states derived from the transition metal (M-d) in semiconducting dichalcogenides of Group TV, VI and VIII and semimetallic compounds of Group V...
FIGURE 27. Schematic representation of structural changes along the H2 + SiH2=SiH2... [Pg.135]

Fig. 13.12 The structures, established by X-ray diffraction, of (a) [Sng]", determined for the salt [Na(crypt-222)]4[Sn9] [J.D. Corbett et al. (1977) J. Am. Chem. Soc., vol. 99, p. 3313], and (b) [Gcg], determined for the compound [K(crypt-222)]3[Ge9] PPh3 [C. Belin et al. (1991) New J. Chem., vol. 15, p. 931] for discussion of cr5T>tand ligands including crypt-222, see Section 10.8. (c) Schematic representations of structure types for selected Zintl ions. See also Figure 13.13. Fig. 13.12 The structures, established by X-ray diffraction, of (a) [Sng]", determined for the salt [Na(crypt-222)]4[Sn9] [J.D. Corbett et al. (1977) J. Am. Chem. Soc., vol. 99, p. 3313], and (b) [Gcg], determined for the compound [K(crypt-222)]3[Ge9] PPh3 [C. Belin et al. (1991) New J. Chem., vol. 15, p. 931] for discussion of cr5T>tand ligands including crypt-222, see Section 10.8. (c) Schematic representations of structure types for selected Zintl ions. See also Figure 13.13.
Fig. 28 (a) Chemical structure of a poly(THF)-BTP polyurethane, (b) Schematic representation of structure and morphology of the metallo-supramolecular polymer network formed by combination of poly(THF)-BTP and Zn. (c) Pictures of a film of the metallo-supramolecular polymer network made from poly(THF)-BTP and Eu before and after stretching. Adapted with permission from [95]. Copyright 2013 The Royal Society of Chemistry... [Pg.370]

Figure 11.20 Schematic representation of structured sintered metal fiber support applied for IL-phase catalysis during gas-phase hydrogenation. (Adapted from [62]. Reproduced with permission from Elsevier.)... Figure 11.20 Schematic representation of structured sintered metal fiber support applied for IL-phase catalysis during gas-phase hydrogenation. (Adapted from [62]. Reproduced with permission from Elsevier.)...
Schematic representation of structure-energy reiationships in SnI reactions. Schematic representation of structure-energy reiationships in SnI reactions.
Figure 12.3 Schematic representation of structures of crystallized PLA material before and after hydrolytic degradation, and of the formation of crystalline residues, taken from Tsuji, with permission from John Wiley Sons, Inc. Figure 12.3 Schematic representation of structures of crystallized PLA material before and after hydrolytic degradation, and of the formation of crystalline residues, taken from Tsuji, with permission from John Wiley Sons, Inc.
A) Schematic representation of structure of (a) DTP-ANDI-COF and (b) DTP-AI rDI-COF. Dotted lines at the peripheiy indicate extended structure, (c) Center-to-center distance from a donor to acceptors in the COF. (d) A graphic view of a 3x3 porous framework. (B) Electronic absorption spectra of (left) DTP-ANDI-COF (green) and (right) DTPA-PyrDI-COF, simple mixture of their monomers (black), TP(OMe)6 (dotted blue), and NDI boronate aster (dotted red), I DI boronate ester (dotted red). For structure of TP(OMe)6, NDI boronate ester and PyrDI boronate ester. [Pg.279]

Figure 3.1 Schematic representation of structure of polymeric material... Figure 3.1 Schematic representation of structure of polymeric material...
Figure 12.24 Schematic representation of structured catalytic packing made by BUCT (a) cross section, (b) side view, and (c) actual photography [118],... Figure 12.24 Schematic representation of structured catalytic packing made by BUCT (a) cross section, (b) side view, and (c) actual photography [118],...
FIGURE 9.15 Schematic representation of structural models of Pb(ll) adsorption onto goe-thite surfaces, (a) Inner-sphere surface complex (b) surface polymerization anchored by some inner-sphere bound Pb(II) ions. (Reprinted with permission from Roe et al. 1991, 367—373. Copyright 1991 American Chemical Society.)... [Pg.325]

Figure 3. Schematical representation of structure types ( (100) projection) ... Figure 3. Schematical representation of structure types ( (100) projection) ...
Figure 8. Schematic representation of structure of a paper sheet, z direction is the thickness. Concentrations in fiber and void spaces are shown as also the average concentrations in the x-y plane. Figure 8. Schematic representation of structure of a paper sheet, z direction is the thickness. Concentrations in fiber and void spaces are shown as also the average concentrations in the x-y plane.
Figure 20 Schematic representation of structural changes during stretching of PP 4.4 Electrical Properties... Figure 20 Schematic representation of structural changes during stretching of PP 4.4 Electrical Properties...
Figure 1.11 Schematic representation of structures of polymers with different molecular architecture. Figure 1.11 Schematic representation of structures of polymers with different molecular architecture.
Schematic representation of structural changes resulting from skeletal densification. Shrinkage occurs isotropically causing no change in the surroundings of the structural elements in either the cylindrical array (top) or the random-close-packed array (bottom) [1451. Schematic representation of structural changes resulting from skeletal densification. Shrinkage occurs isotropically causing no change in the surroundings of the structural elements in either the cylindrical array (top) or the random-close-packed array (bottom) [1451.

See other pages where Schematic representation of structures is mentioned: [Pg.569]    [Pg.195]    [Pg.238]    [Pg.451]    [Pg.94]   
See also in sourсe #XX -- [ Pg.413 , Pg.416 ]




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On the schematic representations of crystal structures

Schematic representation

Schematic structures

Structural representation

Structure representation

Structure schematic representations

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