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Density synthesis

Cluster 2 appears to be unique among Fe-S-containing proteins whose structures have so far been determined, emd it has been termed the hybrid cluster (6) because of its diverse chemical nature. Figure 14 is a schematic drawing of the cluster as interpreted from the final electron density synthesis and the structure refinement. The cluster contains both oxygen and sulfur bridges, and X represents a site whose precise nature has not been determined, but which may contain a partially occupied and/or disordered substrate molecule (see Section III,B,3,b). The environments of the four iron atoms can be described as follows. [Pg.240]

In the present electron density synthesis at 3.0 A resolution the H324(Ne) to E633 side chain distance in the Cu2 to Cu4 pathway is long... [Pg.66]

With the growing importance of modern combinatorial chemistry, additional benefits accrue for catalyst systems that readily adapt to 96 well or higher density synthesis formats. [Pg.468]

Brand F, Dautzenberg H, Jaeger W, Hahn M. Polyelectrolytes with various charge densities synthesis and characterization of diallyldimethylammonium chloride acrylamide copolymers. Appl Macromol Chem 1997 248 41-71. [Pg.789]

N N layers. The one-dimensional electron density synthesis clearly shows that the guest molecules are intercalated between the Cb Cl layers. [Pg.828]

Michaeli I, Overbeek JTG, Voorn MJ (1957) J Polym Sci 23 443 Frugier D (1988) Anionic and cationic copolymers with low charge density synthesis and study of their complex coacervation . Thesis Univ P et M Curie (Paris)... [Pg.150]

Once a polymer geometry has been described, it can be used to predict density, porosity, and so forth. Geometry alone is often of only minor interest. The purpose of computational modeling is often to determine whether properties of the material justify a synthesis elfort. Some of the properties that can be predicted are discussed in the following sections. [Pg.311]

The phenomenon of acoustic cavitation results in an enormous concentration of energy. If one considers the energy density in an acoustic field that produces cavitation and that in the coUapsed cavitation bubble, there is an amplification factor of over eleven orders of magnitude. The enormous local temperatures and pressures so created result in phenomena such as sonochemistry and sonoluminescence and provide a unique means for fundamental studies of chemistry and physics under extreme conditions. A diverse set of apphcations of ultrasound to enhancing chemical reactivity has been explored, with important apphcations in mixed-phase synthesis, materials chemistry, and biomedical uses. [Pg.265]

Dichloroacetic acid [79-43-6] (CI2CHCOOH), mol wt 128.94, C2H2CI2O2, is a reactive intermediate in organic synthesis. Physical properties are mp 13.9°C, bp 194°C, density 1.5634 g/mL, and refractive index 1.4658, both at 20°C. The Hquid is totally miscible in water, ethyl alcohol, and ether. Dichloroacetic acid K = 5.14 X 10 ) is a stronger acid than chloroacetic acid. Most chemical reactions are similar to those of chloroacetic acid, although both chlorine... [Pg.88]

P. E. Eaton, in S. Iyer, ed.. Proceedings of the Ninth Annual Working Group Institute on the Synthesis of High Energy Density Materials, U.S. Army, ARDEC, Picatinny Arsenal, N.J., June 90. [Pg.30]

Poly(ethylene oxide). The synthesis and subsequent hydrolysis and condensation of alkoxysilane-terniinated macromonomers have been studied (39,40). Using Si-nmr and size-exclusion chromatography (sec) the evolution of the siUcate stmctures on the alkoxysilane-terniinated poly(ethylene oxide) (PEO) macromonomers of controlled functionahty was observed. Also, the effect of vitrification upon the network cross-link density of the developing inorganic—organic hybrid using percolation and mean-field theory was considered. [Pg.329]

The second type of solution polymerization concept uses mixtures of supercritical ethylene and molten PE as the medium for ethylene polymerization. Some reactors previously used for free-radical ethylene polymerization in supercritical ethylene at high pressure (see Olefin POLYMERS,LOW DENSITY polyethylene) were converted for the catalytic synthesis of LLDPE. Both stirred and tubular autoclaves operating at 30—200 MPa (4,500—30,000 psig) and 170—350°C can also be used for this purpose. Residence times in these reactors are short, from 1 to 5 minutes. Three types of catalysts are used in these processes. The first type includes pseudo-homogeneous Ziegler catalysts. In this case, all catalyst components are introduced into a reactor as hquids or solutions but form soHd catalysts when combined in the reactor. Examples of such catalysts include titanium tetrachloride as well as its mixtures with vanadium oxytrichloride and a trialkyl aluminum compound (53,54). The second type of catalysts are soHd Ziegler catalysts (55). Both of these catalysts produce compositionaHy nonuniform LLDPE resins. Exxon Chemical Company uses a third type of catalysts, metallocene catalysts, in a similar solution process to produce uniformly branched ethylene copolymers with 1-butene and 1-hexene called Exact resins (56). [Pg.400]

Titanium Dibromide. Titanium dibromide [13873-04-5] a black crystalline soHd, density 4310 kg/m, mp 1025°C, has a cadmium iodide-type stmcture and is readily oxidized to trivalent titanium by water. Spontaneously flammable in air (142), it can be prepared by direct synthesis from the elements, by reaction of the tetrabromide with titanium, or by thermal decomposition of titanium tribromide. This last reaction must be carried out either at or below 400°C, because at higher temperatures the dibromide itself disproportionates. [Pg.131]

The primary transporter of cholesterol in the blood is low density Hpoprotein (LDL). Once transported intraceUularly, cholesterol homeostasis is controlled primarily by suppressing cholesterol synthesis through inhibition of P-hydroxy-P-methyl gluterate-coenzyme A (HMG—CoA) reductase, acyl CoA—acyl transferase (ACAT), and down-regulation of LDL receptors. An important dmg in the regulation of cholesterol metaboHsm is lovastatin, also known as mevinolin, MK-803, and Mevacor, which is an HMG—CoA reductase inhibitor (Table 5). [Pg.130]

There are some recent examples of this type of synthesis of pyridazines, but this approach is more valuable for cinnolines. Alkyl and aryl ketazines can be transformed with lithium diisopropylamide into their dianions, which rearrange to tetrahydropyridazines, pyrroles or pyrazoles, depending on the nature of the ketazlne. It is postulated that the reaction course is mainly dependent on the electron density on the carbon termini bearing anionic charges (Scheme 65) (78JOC3370). [Pg.42]

Ceroplastol synthesis, 1, 428 Cetyl alcohol synthesis, 1, 478 Chaetoglobasins structures, 4, 376 Chalcone, o -azido-2 -oxy-synthesis, 3, 823 Chalcone, 2-hydroxy-reduction, 3, 751 Chalcone, 2 -hydroxy-mass spectra, 3, 618 Chalcone dibromides flavone synthesis from, 3, 823 Chalcones polymers, 1, 304 Chanoclavine synthesis, 6, 423 Charge density waves in stacks of ions, 1, 351-352 Chartreusin... [Pg.577]

Isothiazole-4,5-dicarboxylic acid, 3-phenyl-dimethyl ester synthesis, S, 150 Isothiazole-5-glyoxylic acid ethyl ester reduction, 6, 156 Isothiazole-4-mercurioacetate reactions, 6, 164 Isothiazole-5-mercurioacetate reactions, 6, 164 Isothiazoles, 6, I3I-I75 acidity, 6, 141 alkylation, 6, 148 aromaticity, S, 32 6, 144-145 basicity, 6, I4I biological activity, 6, 175 boiling points, 6, I43-I44, 144 bond fixation, 6, 145 bond orders, 6, I32-I34 calculated, 6, 133 bromination, S, 58 6, 147 charge densities, 6, 132-134 cycloaddition reactions, 6, 152 desulfurization, S, 75 6, 152 deuteration, S, 70... [Pg.683]


See other pages where Density synthesis is mentioned: [Pg.234]    [Pg.81]    [Pg.126]    [Pg.383]    [Pg.432]    [Pg.48]    [Pg.496]    [Pg.532]    [Pg.234]    [Pg.81]    [Pg.126]    [Pg.383]    [Pg.432]    [Pg.48]    [Pg.496]    [Pg.532]    [Pg.1957]    [Pg.2811]    [Pg.3]    [Pg.51]    [Pg.347]    [Pg.481]    [Pg.752]    [Pg.1038]    [Pg.324]    [Pg.24]    [Pg.180]    [Pg.366]    [Pg.366]    [Pg.45]    [Pg.367]    [Pg.169]    [Pg.428]    [Pg.325]    [Pg.131]    [Pg.313]    [Pg.88]    [Pg.94]    [Pg.530]    [Pg.621]    [Pg.670]   
See also in sourсe #XX -- [ Pg.34 , Pg.35 , Pg.36 , Pg.37 , Pg.38 ]

See also in sourсe #XX -- [ Pg.34 , Pg.35 , Pg.36 , Pg.37 , Pg.38 ]




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Charge density, polyelectrolyte synthesis

Fourier synthesis of electron density

High-density lipoproteins synthesis

High-density polyethylene, synthesis

Low-density lipoproteins synthesis

Low-density polyethylene, synthesis

Polyanilines, synthesis density

Very-low-density lipoproteins synthesis

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