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Schematic of structure

Fig. 45. Schematics of structures formed on Au(lll) by Te atoms (Adapted from ref. [239]) a) Schematic diagram of the Au(lll)(13 x 13)-Te structure, l/3rds coverage, b) Schematic diagram of the Au(l 11)( /7 x /l3)-Te structure, 4/1 lths coverage, c) Schematic diagram of the Au(l 11)(3 x 3)-Te structure, 4/9ths coverage. Fig. 45. Schematics of structures formed on Au(lll) by Te atoms (Adapted from ref. [239]) a) Schematic diagram of the Au(lll)(13 x 13)-Te structure, l/3rds coverage, b) Schematic diagram of the Au(l 11)( /7 x /l3)-Te structure, 4/1 lths coverage, c) Schematic diagram of the Au(l 11)(3 x 3)-Te structure, 4/9ths coverage.
Fig. 2. Schematic of structural models proposed for the FeMo-cofactor... Fig. 2. Schematic of structural models proposed for the FeMo-cofactor...
Fig. 3 (A) Schematic of structures of various types of carbons that can insert lithium reversibly. (B) Charge and discharge characteristics of natural graphite powder (NG-7) at the first cycle in the 1 M LiC104/EC -I-DEC (1 1 vol/vol). (From Refl l)... Fig. 3 (A) Schematic of structures of various types of carbons that can insert lithium reversibly. (B) Charge and discharge characteristics of natural graphite powder (NG-7) at the first cycle in the 1 M LiC104/EC -I-DEC (1 1 vol/vol). (From Refl l)...
Fig. 3. Gold nanoparticles are formed on the surface of (A) A fused MMF-CF-MMF structure and a fused SMF-GIF- CF-MMF structure, (B) Ray Tracing schematic of Structure B, which is an in-line fiber structure consisting of single mode, graded index, coreless, and multimode fibers to expand the Gaussian beam to the surface of the coreless fiber. Fig. 3. Gold nanoparticles are formed on the surface of (A) A fused MMF-CF-MMF structure and a fused SMF-GIF- CF-MMF structure, (B) Ray Tracing schematic of Structure B, which is an in-line fiber structure consisting of single mode, graded index, coreless, and multimode fibers to expand the Gaussian beam to the surface of the coreless fiber.
Figure 2. Schematic of structure of block copolymer films. Open circles are DMS segments, shaded lozenges are BPAC segments, (a) At low surface pressures (b) at maximum compression. Figure 2. Schematic of structure of block copolymer films. Open circles are DMS segments, shaded lozenges are BPAC segments, (a) At low surface pressures (b) at maximum compression.
FIGURE 2.57 Schematic of structural reaction injection molding (SRIM). [Pg.219]

Fig. 10 Series of 15 dipolar polymeric lanthanide complexes of trans-citmamic acid, [Ln(C9H702)3ln. Above Schematic of structural properties of the complexes formed with different coordination numbers of 9 and 7 in the non-centrosymmetric space groups R3c and P2], respectively Below The variation, as a function of the number of unpaired electrons, of the relative SHG intensity in the solid state, measured using 800 nm excitation (adapted frran [124])... Fig. 10 Series of 15 dipolar polymeric lanthanide complexes of trans-citmamic acid, [Ln(C9H702)3ln. Above Schematic of structural properties of the complexes formed with different coordination numbers of 9 and 7 in the non-centrosymmetric space groups R3c and P2], respectively Below The variation, as a function of the number of unpaired electrons, of the relative SHG intensity in the solid state, measured using 800 nm excitation (adapted frran [124])...
Figure 9.15. Schematic of structures of clay and pillared clay, with cation sites. The pillars are more closely spaced than depicted. Figure 9.15. Schematic of structures of clay and pillared clay, with cation sites. The pillars are more closely spaced than depicted.
Figure 39 Schematic of structure evolution during the field-induced liquid-to-solid transition for an liR suspension. The gel point of a static sample occurs at low field strengths, as determined with tg5 method. Under a steady shear, the transition shifts to high field strengths, as determined with the yield stress method. Reproduced with permission from B. D. Chin and II. II. Winter, Rheol. Acta, 41(2002)265. Figure 39 Schematic of structure evolution during the field-induced liquid-to-solid transition for an liR suspension. The gel point of a static sample occurs at low field strengths, as determined with tg5 method. Under a steady shear, the transition shifts to high field strengths, as determined with the yield stress method. Reproduced with permission from B. D. Chin and II. II. Winter, Rheol. Acta, 41(2002)265.
Figure 2.17 Schematic of structures observed in the early stage of phase separation in a polymer blend by (a) spinodal decomposition and (b) nucleation and growth... Figure 2.17 Schematic of structures observed in the early stage of phase separation in a polymer blend by (a) spinodal decomposition and (b) nucleation and growth...
Figure 3.1 shows a typical schematic of structure comparison of Y-type and our Seesaw-type AB2 macromonomers and the resultant hyperbranched polymers. As shown, instead of putting two reactive B groups on one end (Y-type), we attach them, respectively, at two ends of our macromonomer and move the reactive A group... [Pg.14]

Pig. 3.1 Schematic of structure comparison of Y-type and Seesaw-type AB2 macromonomer and the corresponding hyperbranched polymers... [Pg.15]

Figure 1.12 Schematic of structural and chemical composition of amylose and amylopectin. Reprinted with permission from Sweedman et al. (2013]. Copyright 2013 Elsevier. Figure 1.12 Schematic of structural and chemical composition of amylose and amylopectin. Reprinted with permission from Sweedman et al. (2013]. Copyright 2013 Elsevier.
See other pages where Schematic of structure is mentioned: [Pg.208]    [Pg.209]    [Pg.216]    [Pg.385]    [Pg.14]   
See also in sourсe #XX -- [ Pg.67 , Pg.68 ]



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Schematic structures

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