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Left orientation

Use alum (fanshi), Turkestan salt (rongyan), lake salt (luxian), and arseno-lite (yushi), heating them first for twenty days also use left-oriented oyster shells zuogu muli) from Donghai, red clay chishi zhi), and talc (huashi). Take the desired amount of these seven substances in equal parts, and pound them together ten thousand times until they become powder-like. [Pg.166]

Pasteur made up a solution of the left-oriented crystals and found that it rotated polarized light in one direction. A solution of right-handed crystals gave the opposite rotation. He made up a mixture of equal amounts of both right-handed and left-handed crystals, and it had no effect on polarized light. (The term racemic mixture has come to indicate a mixture that contains equal portions of the two possible orientations of a chiral compound.) He told Biot, who by now was an elderly man, and Biot did not believe him. Pasteur went to Biot s laboratory, used Biot s chemicals, did the separation in front of him, and let Biot make up the solutions for testing. They had exactly the properties Pasteur claimed. Biot became an enthusiastic supporter of Pasteur s work. [Pg.252]

Figure 2.22 Typical micromechanical mechanisms in p-iPP with the characteristic lamellar morphology after uniaxial tensile deformation at room temperature left orientation of the lamellae... Figure 2.22 Typical micromechanical mechanisms in p-iPP with the characteristic lamellar morphology after uniaxial tensile deformation at room temperature left orientation of the lamellae...
Left-Oriented Descriptors Right-Oriented Descriptors ... [Pg.100]

Figure 7 V-butt weld with perpendicular grain orientation and an inclination of the interface of 15° left without, right with backwall breaking notch... Figure 7 V-butt weld with perpendicular grain orientation and an inclination of the interface of 15° left without, right with backwall breaking notch...
The 3D representation of the test object can be rotated by means of an ARCBALL interface. Clicking on the main client area will produce a circle which is actually the silhouette of a sphere. Dragging the mouse rotates the sphere, and the model moves aceordingly. An arc on the surface of the sphere is drawn for visual feedback of orientation additionally a set of coordinate axes in the bottom left comer provides further feedback. [Pg.767]

Figure Cl.5.14. Fluorescence images of tliree different single molecules observed under the imaging conditions of figure Cl.5.13. The observed dipole emission patterns (left column) are indicative of the 3D orientation of each molecule. The right-hand column shows the calculated fit to each observed intensity pattern. Molecules 1, 2 and 3 are found to have polar angles of (0,( ))=(4.5°,-24.6°), (-5.3°,51.6°) and (85.4°,-3.9°), respectively. Reprinted with pennission from Bartko and Dickson [148]. Copyright 1999 American Chemical Society. Figure Cl.5.14. Fluorescence images of tliree different single molecules observed under the imaging conditions of figure Cl.5.13. The observed dipole emission patterns (left column) are indicative of the 3D orientation of each molecule. The right-hand column shows the calculated fit to each observed intensity pattern. Molecules 1, 2 and 3 are found to have polar angles of (0,( ))=(4.5°,-24.6°), (-5.3°,51.6°) and (85.4°,-3.9°), respectively. Reprinted with pennission from Bartko and Dickson [148]. Copyright 1999 American Chemical Society.
Figure C2.2.4. Types of smectic phase. Here tire layer stacking (left) and in-plane ordering (right) are shown for each phase. Bond orientational order is indicated for tire hexB, SmI and SmF phases, i.e. long-range order of lattice vectors. However, tliere is no long-range translational order in tliese phases. Figure C2.2.4. Types of smectic phase. Here tire layer stacking (left) and in-plane ordering (right) are shown for each phase. Bond orientational order is indicated for tire hexB, SmI and SmF phases, i.e. long-range order of lattice vectors. However, tliere is no long-range translational order in tliese phases.
Figure C2.17.6. Transmission electron micrograph and its Fourier transfonn for a TiC nanocrystal. High-resolution images of nanocrystals can be used to identify crystal stmctures. In tliis case, tire image of a nanocrystal of titanium carbide (right) was Fourier transfonned to produce tire pattern on tire left. From an analysis of tire spot geometry and spacing, one can detennine that tire nanocrystal is oriented witli its 11001 zone axis parallel to tire viewing direction [217]. Figure C2.17.6. Transmission electron micrograph and its Fourier transfonn for a TiC nanocrystal. High-resolution images of nanocrystals can be used to identify crystal stmctures. In tliis case, tire image of a nanocrystal of titanium carbide (right) was Fourier transfonned to produce tire pattern on tire left. From an analysis of tire spot geometry and spacing, one can detennine that tire nanocrystal is oriented witli its 11001 zone axis parallel to tire viewing direction [217].
FIGURE 27 1 Electro static potential maps of the 20 common amino acids listed in Table 27 1 Each ammo acid is oriented so that Its side chain is in the upper left corner The side chains affect the shape and properties of the ammo acids... [Pg.1114]

Traditionally, the electron and proton transport pathways of photosynthetic membranes (33) have been represented as a "Z" rotated 90° to the left with noncycHc electron flow from left to right and PSII on the left-most and PSI on the right-most vertical in that orientation (25,34). Other orientations and more complex graphical representations have been used to depict electron transport (29) or the sequence and redox midpoint potentials of the electron carriers. As elucidation of photosynthetic membrane architecture and electron pathways has progressed, PSI has come to be placed on the left as the "Z" convention is being abandoned. Figure 1 describes the orientation in the thylakoid membrane of the components of PSI and PSII with noncycHc electron flow from right to left. [Pg.39]

Fig. 4.6. Piezoelectric pulse diagrams can be used to obtain explicit representations of the time dependent electric fields in piezoelectric substances. The magnitudes and orientations of these electric fields are critical to development of shock-induced conduction. As an example, the diagram on the left shows the polarization and displacement relations for a location at the input electrode. The same functions for a location within the crystal is shown on the right (after Davison and Graham [79D01]). Fig. 4.6. Piezoelectric pulse diagrams can be used to obtain explicit representations of the time dependent electric fields in piezoelectric substances. The magnitudes and orientations of these electric fields are critical to development of shock-induced conduction. As an example, the diagram on the left shows the polarization and displacement relations for a location at the input electrode. The same functions for a location within the crystal is shown on the right (after Davison and Graham [79D01]).
In the plus-x orientation, the region behind the plastic wave is treated as a conductor. Accordingly, in the electrical model, the left electrode is moving with the velocity of the plastic wave. Otherwise, the analysis proceeds as in the case of the elastic-dielectric. For convenience it is assumed that 3 = 2 = i. The thicknesses of the two dielectric regions are = I and I2 — ([/, — U2)t. Solution for the current is then... [Pg.100]

See other pages where Left orientation is mentioned: [Pg.363]    [Pg.197]    [Pg.17]    [Pg.5]    [Pg.1023]    [Pg.194]    [Pg.24]    [Pg.654]    [Pg.102]    [Pg.87]    [Pg.217]    [Pg.363]    [Pg.197]    [Pg.17]    [Pg.5]    [Pg.1023]    [Pg.194]    [Pg.24]    [Pg.654]    [Pg.102]    [Pg.87]    [Pg.217]    [Pg.1075]    [Pg.1187]    [Pg.2561]    [Pg.2821]    [Pg.329]    [Pg.556]    [Pg.1027]    [Pg.329]    [Pg.6]    [Pg.449]    [Pg.74]    [Pg.250]    [Pg.132]    [Pg.243]    [Pg.23]    [Pg.127]    [Pg.10]    [Pg.96]    [Pg.36]    [Pg.385]    [Pg.216]    [Pg.29]   
See also in sourсe #XX -- [ Pg.103 ]



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LEFT

Left-handed orientation

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