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A evolutions

Figure Bl.15.10. FT EPR. (A) Evolution of the magnetization during an FT EPR experiment (rotating frame representation). (B) The COSY FT EPR experiment. Figure Bl.15.10. FT EPR. (A) Evolution of the magnetization during an FT EPR experiment (rotating frame representation). (B) The COSY FT EPR experiment.
FIG. 33 (a) Evolution of a system of 128 chains quenched at times t — 0 from a state with e = —4.0 (upper left corner) to e — —0.4. Snapshots are shown in time increments At — 65536 MCS (in typewriter fashion from left to right), (b) Evolution of the same system but for time increments At — 524288 MCS [23]. [Pg.621]

Figure 29. (a) Evolution of the absorption spectra of an electro-chromic polypyrrole as a function of the oxidation potential obtained during voltammetry between -900 and 400 mV from a 2.5 M LiCI04 aqueous solution. The voltammetry was performed at a scan rate of 20 mV s 1. (From Ref. 161). (b) Evolution of the absorption spectra of an electrochromic polypyrrole as a function of the reduction potential obtained during voltammetry between 400 and -900 mV from a 2.5 M LiCI04 aqueous solution. The voltammetry was performed at a scan rate of 20 mV s 1. (From Ref. 161). [Pg.363]

Figure 9. Arc length as a function of time for three time transient calculations, (a) Evolution of interface from an unstable planar interface to a shape in the (lA -family. (b) Evolution of perturbation to a shape in the (up-family for P < Continued on next page. Figure 9. Arc length as a function of time for three time transient calculations, (a) Evolution of interface from an unstable planar interface to a shape in the (lA -family. (b) Evolution of perturbation to a shape in the (up-family for P < Continued on next page.
Figure 21. (a) Evolution of PL intensity at 1540 nm in both pumping conditions as a function of the annealing temperature for the Er... [Pg.287]

Fig. 1 Schematic representations of the two general FBDD approaches, (a) Evolution of the fragment in the binding site of a generic target, (b) Fragment-linking approach... Fig. 1 Schematic representations of the two general FBDD approaches, (a) Evolution of the fragment in the binding site of a generic target, (b) Fragment-linking approach...
A Evolution only considered 27 elements for the process of life ... [Pg.89]

Fig. 3.2 (a) Evolution of the XRD patterns of 2Mg-Fe mixture reactively milled sequentially for various times under 1MP2 mode in 880 kPa of hydrogen. For comparison the XRD pattern of the mixture milled continuously for 270 h is also shown, (b) Morphology of 2Mg-Fe mixture reactively milled for 270 h in a continuous manner... [Pg.201]

Figure 14.3 (a) Evolution of the photoluminescence spectra from 555 nm emitting QDs... [Pg.293]

Fig. 19. Simulation of soot deposition on a filter wall, (a) Evolution of soot deposits (gray) in the wall (black is solid, white is pore space) and incipient cake formation (b) pressure drop as function of challenge soot mass demonstrating the deep-bed to cake filtration transition (c) visualization of soot deposition in an extruded ceramic (granular) filter wall and (d) development of soot deposits (black) and soot mass fraction in the wall (solid material is gray) to the onset of cake formation. Soot mass fraction scale is from 0 (violet) to the inflow value (red). In (d) the velocity on a section through the filter wall is shown, with overlay of the soot deposit shapes (see Plate 9 in Color Plate Section at the end of this book). Fig. 19. Simulation of soot deposition on a filter wall, (a) Evolution of soot deposits (gray) in the wall (black is solid, white is pore space) and incipient cake formation (b) pressure drop as function of challenge soot mass demonstrating the deep-bed to cake filtration transition (c) visualization of soot deposition in an extruded ceramic (granular) filter wall and (d) development of soot deposits (black) and soot mass fraction in the wall (solid material is gray) to the onset of cake formation. Soot mass fraction scale is from 0 (violet) to the inflow value (red). In (d) the velocity on a section through the filter wall is shown, with overlay of the soot deposit shapes (see Plate 9 in Color Plate Section at the end of this book).
C This pulse sequence, the popular homonuclear 2D COSY (COrelation Speciro-scopY) experiment, was designed to determine the entire H/ H-coupling network of a molecule within a single experiment. The sequence consist of all four elements, i.e. a preparation, a evolution, a mixing and a detection period. The evolution period serves to introduce the second time (tl) domain of a 2D experiment and in the mixing period, which is actually a pulse, polarizations are exchanged among the coupled spins. [Pg.45]

Garcia del Pozo J, Isusi L, Carvajal A, Martin I, Sainz M, Garcia del Pozo V, Velasco A. Evolution del consumo de farmacos antipsicoticos en Castilla y Leon (1990-2001). Rev Esp Salud Publica 2003 77 725-33. [Pg.680]

J. P. Vigier, and M. Fuchs, Tendance vers un etat d equilibre stable de phenomenes sounds a evolution Markovienne, C. R. Acad. Sci. 9, 1120 (note) (1956). [Pg.196]

Fig. 16.2. (a) Evolution of the wavepacket in the excited electronic state created by a laser pulse centered at to = 90 fs with a width of 50 fs. The times are given in femtoseconds, (b) Schematic illustration of the potentials in the lower and upper electronic states and of the excitation process. By courtesy of V. Engel. [Pg.370]

Fig. 10.61 (a) Evolution of the packed solids/melt mixtures obtained by carcass analysis during... [Pg.581]

FIGURE 7.2 (A) Evolution of total production and total exportations of Madeira wines... [Pg.214]

Figure 2.14. Evolution with temperature of the full width y0 at half maximum of the 0-0 absorption peak. Hollow circles represent our results from Kramers-Kronig analysis, (a) Evolution between 0 and 77 K. The solid line was drawn using equation (2.126) and adjusted parameters y, =72cm 1, hfi = 27cm" . The dashed line connects the results of our model (2.127)—(2.130) for six different temperatures, (b) Evolution between 0 and 300 K. The full circles are taken from ref. 62. This summary of the experimental results shows the linear behavior between 30 and 50 K., and the sublinear curvature at temperatures above 200 K. [Pg.94]

Sederquist, R. A., "Evolution of Steam Reformers for Commercial Fuel Cell Power Plants," Symposium on Reformers and Hydro gen Plants, March 7-9, 1978. Santa Barbara, California... [Pg.188]

Martin MJ, Rayner JC, Gagneux P, Barnwell JW, Varki A. Evolution of human-chimpanzee differences in malaria susceptibility relationship to human genetic loss of N-glycolylneuraminic acid. Proc Natl Acad Sci USA 2005 102(36) 12819-24. [Pg.334]

Shmakov et al. (1995) TEM Gamma-iron oxide Vacancy ordering + + n.a. Evolution of real structure... [Pg.325]

FIGURE 59 (A) Evolution of Mo K-edge position (relative to the edge position of M0O3)... [Pg.443]

Figure 2 Salinization of the Jordan River, (a) Evolution of the chloride content during the twentieth century as recorded in Ahdalla Bridge, the southern point of the Jordan River before its entry into the Dead Sea. (b) Chloride variation transects along the Jordan River. Distance in km refers to the beginning of the river flow (Alumot dam) below the Sea of Galilee (source Vengosh et al., 2001). Figure 2 Salinization of the Jordan River, (a) Evolution of the chloride content during the twentieth century as recorded in Ahdalla Bridge, the southern point of the Jordan River before its entry into the Dead Sea. (b) Chloride variation transects along the Jordan River. Distance in km refers to the beginning of the river flow (Alumot dam) below the Sea of Galilee (source Vengosh et al., 2001).
FIG. 5.10 (A) Evolution of the birefringence, induced by polarized blue.green light... [Pg.156]

FIG- S. 12 (A) Evolution of the birefringence. An. , induced by poiarized white ii in a copolymer film (KWI9,22 pm) without filters (/) or through grey filters of different optical density (2-f) (B) the An value Induced for 10 min, versus the light intensity. [Pg.157]

Gunther, D.A. Evolution of equipment, techniques for industrial EtO sterilization. Am. Perfume Cosmet. 1970, 85, 35-38. [Pg.3527]

A. Evolution of renal failure. B. First renal biopsy. C. Second renal biopsy. Note the important cellular infiltration in both biopsies. Normal aspect of glomeruli. B-C H E staining, orig. magn. x350. [Pg.410]

Figure 5. Tafel plots for (a) evolution, (b) CO formation, and (c) HCOOCHj formation under 40 atm (25°C). Figure 5. Tafel plots for (a) evolution, (b) CO formation, and (c) HCOOCHj formation under 40 atm (25°C).
Fig. 4 (A) Evolution of htext in time for U = 8, De = 15, Er = 8 X 10 , A/H — 10 and (B) scaling for hi i when U/De is varied. The data points are numerical results and the dotted line indicates the square-root law of Eq. (21). (Erom Ref... Fig. 4 (A) Evolution of htext in time for U = 8, De = 15, Er = 8 X 10 , A/H — 10 and (B) scaling for hi i when U/De is varied. The data points are numerical results and the dotted line indicates the square-root law of Eq. (21). (Erom Ref...
Medeiros, A. A., Evolution and dissemination of )9-lactamases accelerated by generation of jS-lactam antiobiotics. Clin. Infect. Dis. 24, S19-S45 (1997). [Pg.123]

Fig. 14. SiH penetration into a-Si H films (from Ramalingam et al., 199Sa.b). (a) Evolution of the height coordinate of the radical s center of mass for four MD trajectories, A, B, C, and D, of radical impingement on a-Si H surfaces in C and D, the radical penetrates into the amorphous film, (b) Energy evolution, A (/), along trajectories B and D shown in a. (c) Schematic illustration of a common mechanism of radical penetration through an H-passivated nanocavity emanating from the surface of the film. Fig. 14. SiH penetration into a-Si H films (from Ramalingam et al., 199Sa.b). (a) Evolution of the height coordinate of the radical s center of mass for four MD trajectories, A, B, C, and D, of radical impingement on a-Si H surfaces in C and D, the radical penetrates into the amorphous film, (b) Energy evolution, A (/), along trajectories B and D shown in a. (c) Schematic illustration of a common mechanism of radical penetration through an H-passivated nanocavity emanating from the surface of the film.

See other pages where A evolutions is mentioned: [Pg.319]    [Pg.328]    [Pg.967]    [Pg.468]    [Pg.53]    [Pg.630]    [Pg.914]    [Pg.522]    [Pg.66]    [Pg.270]    [Pg.157]    [Pg.317]    [Pg.522]    [Pg.286]    [Pg.80]    [Pg.130]    [Pg.218]    [Pg.208]   
See also in sourсe #XX -- [ Pg.475 ]




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Directed Evolution as a Means to Engineer Enantioselective Enzymes

Evolution after switching a perturbation

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Evolution of a Chemical Equation

Evolution of a system

Evolution study from a spectra set

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Mutation as Driving Force of Evolution

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Time evolution of a one-dimensional free particle wavepacket

Time evolution on the trajectories of a dynamical system

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