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Enantiomorphic

A minor chemical use for many of the commoner alkaloids is the resolution of racemic compounds (often acids) into their optically active enantiomorphs. [Pg.21]

Polymer Solutions. Perhaps the most extensively studied macromolecular Hquid crystals are the synthetic polypeptides, such as poly( y-benzyl L-glutamate) [25513-40-0] (PBLG). PBLG is a homopolymer of the L-enantiomorph of a single amino acid with the foUowiag repeat unit. [Pg.201]

The base boiled in methyl alcoholic solution with methyl iodide and potassium hydroxide, forms a gelatinous methiodide, which was converted by silver chloride into the methochloride. The latter when boiled with 20 per cent, solution of sodium hydroxide, produced a mixture of methine bases, which were separated as the methiodides into 0-methylbebeerine-methine methiodide B, m.p. 237° (cf. p. 375), and a lasvorotatory form, m.p. 190°, which proved to be the lasvo-enantiomorph of d-O-methyl-bebeerinemethine methiodide (form C, p. 375). Chondrofoline therefore belongs to the bebeerine type represented by formula (III). In it R = H, the single phenolic hydroxyl is at ORj or OR4 and the remaining groups, OR2, OR 3, OR or alternatively ORj, OR2, OR 3 are methoxyl groups (King,i 1940). [Pg.365]

Racemic and Mesotartaric Acids.—These two acids represent two inactive types of compounds containing a< yminct7 ic carbon atoms (see above). Apart from certain well-marked differences in physical properties they also differ in one important feature racemic acid can be lesoh-ed into its optical enantiomorphs, whereas mesotartaric acid cannot. The latter belongs to what is termed the inactive indivisible type. If we examine the structuial formula of tartaric acid it will l>e seen that it possesses two asyimnetric carbon atoms, denoted in the formula by thick type. [Pg.264]

Optical isomers, enantiomorphs or enantiomers, as they are also known, are pairs of molecules... [Pg.919]

Two mols, for example, 270 grams, of racemic a-methylphenethylamine base are reacted with one mol (150 grams) of d-tartaric acid, thereby forming dl-a-methylphenethylamine d-tartrate, a neutral salt. The neutral salt thus obtained is fully dissolved by the addition of sufficient, say about 1 liter, of absolute ethanol, and heating to about the boiling point. The solution is then allowed to cool to room temperature with occasional stirring to effect crystallization. The crystals are filtered off and will be found to contain a preponderance of the levo enantiomorph. [Pg.459]

Consider a methane molecule CH, and suppose that some or all of its hydrogen atoms are replaced by some other monovalent atom. If the atoms attached to the carbon are all different, that is, the carbon atom is asymmetric, the resulting molecule is chiral and exists in two so-called enantiomorphic forms mirror images of each other. (For further information on chirality see the interesting expository paper [PreV76]). [Pg.129]

In the a modifications of i-PP, bilayers of macromolecules are stacked one on the top of the other in such a way that the top layer on one bilayer and the bottom layer of the bilayer in contact are made up of helices which are enantiomorphous. such helices are regularly anticlined for the ordered a2 modification, more or less at chance isoclined or anticlined for the disordered modifications. [Pg.197]

Extensive studies of stereoselective polymerization of epoxides were carried out by Tsuruta et al.21 s. Copolymerization of a racemic mixture of propylene oxide with a diethylzinc-methanol catalyst yielded a crystalline polymer, which was resolved into optically active polymers216 217. Asymmetric selective polymerization of d-propylene oxide from a racemic mixture occurs with asymmetric catalysts such as diethyzinc- (+) bomeol218. This reaction is explained by the asymmetric adsorption of monomers onto the enantiomorphic catalyst site219. Furukawa220 compared the selectivities of asymmetric catalysts composed of diethylzinc amino acid combinations and attributed the selectivity to the bulkiness of the substituents in the amino acid. With propylene sulfide, excellent asymmetric selective polymerization was observed with a catalyst consisting of diethylzinc and a tertiary-butyl substituted a-glycol221,222. ... [Pg.18]

If a molecule is nonsuperimposable on its miixor image, the mirror image must be a different molecule, since superimposability is the same as identity. In each case of optical activity of a pure compound there are two and only two isomers, called enantiomers (sometimes enantiomorphs), which differ in structure only in the left-and right-handedness of their orientations (Fig. 4.1). Enantiomers have identical physical and chemical properties except in two important respects ... [Pg.125]

One component obeys the Bemoullian model the other two obey the enantiomorphic- site model. Similarly, the NMR data of fractionated copolymers can be used to demonstrate the presence of multiple components in the copolymers. An example is shown of ethylene-propylene copolymers where the NMR/fractionation data are used to show the presence of two or three catalytic sites. [Pg.174]

An excellent way to treat such data is to use reaction probability models.(1,2) In the NMR analysis of tacticity, it is frequently possible to distinguish whether the configuration is chain-end controlled or catalytic-site controlled during polymerization. Various statistical models have been proposed. The chain-end controlled models include Bemoullian (B), and first- and second-order Markovian (Ml and M2) statistics.(1) The simplest catalytic-site controlled model is the enantiomorphic site (E) model.(3) The relationship between the chain-end and catalytic-site controlled models and possible hybrid models have been delineated in a recent article.(4)... [Pg.174]

Sample II being someWhat more syndiotactic. Thus, the selectivity control agent (and any attendant changes in synthetic procedure) appears to change (1) the amount of polymer made at different sites (wj w2 w3 = 39 42 20), and (2) the nature of the Bemoullian polymer. It appears from this analysis that the nature of the enantiomorphic catalytic sites remains unchanged in the absence of the selectivity control agent. [Pg.181]

By 1938, one fact was clearly established. Sweet compounds, unlike salty and sour compounds, are found in all classes of chemical compounds, including such inorganic salts as beryllium ( glucinium ) and lead salts. They are also found among compounds of all molecular shapes and sizes, and stereochemical changes may result in a very dramatic change in the taste, as seen in the gustatory differences between enantiomorphs. [Pg.207]

A chiral object and the opposite object formed by inversion form a pair of enan-tiomorphs. If an enantiomorph is a molecular entity, it is called an enantiomer. An equimolar mixture of enantiomers is a racemate. [Pg.83]

In literature, SOHNCKE space-group types are often termed chiral space groups , which is not correct. Most chiral molecular compounds do not crystallize in a chiral (enantiomorphic) space group. For details see [86]. [Pg.83]

See other pages where Enantiomorphic is mentioned: [Pg.157]    [Pg.135]    [Pg.1149]    [Pg.873]    [Pg.272]    [Pg.255]    [Pg.211]    [Pg.361]    [Pg.365]    [Pg.375]    [Pg.447]    [Pg.4]    [Pg.307]    [Pg.342]    [Pg.418]    [Pg.283]    [Pg.126]    [Pg.176]    [Pg.178]    [Pg.179]    [Pg.180]    [Pg.1150]    [Pg.83]    [Pg.214]    [Pg.287]    [Pg.357]    [Pg.361]    [Pg.476]    [Pg.21]    [Pg.298]    [Pg.137]   
See also in sourсe #XX -- [ Pg.8 , Pg.19 , Pg.20 , Pg.98 , Pg.102 , Pg.109 , Pg.155 , Pg.173 , Pg.174 , Pg.176 ]

See also in sourсe #XX -- [ Pg.104 ]

See also in sourсe #XX -- [ Pg.47 ]



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Active sites enantiomorphic control

Asymmetric Autocatalysis Utilizing Enantiomorphous Inorganic Crystals as an Initial Source of Chirality

Asymmetric molecule, enantiomorphic

Asymmetric molecule, enantiomorphic forms

Catalyst, enantiomorphous

Conformational enantiomorphism

Cooling Enantiomorphism

Crystal enantiomorphous

Differentiability enantiomorphs

Direct methods enantiomorph

Elements enantiomorphic

Enantiomers, enantiomorphs

Enantiomorph selection

Enantiomorph specification

Enantiomorphic catalyst

Enantiomorphic configuration, surface

Enantiomorphic crystals

Enantiomorphic orbit

Enantiomorphic pair

Enantiomorphic pair space

Enantiomorphic pair space groups

Enantiomorphic property

Enantiomorphic selectivity

Enantiomorphic site control

Enantiomorphic site control statistical model

Enantiomorphic site stereocontrol

Enantiomorphic sites model

Enantiomorphic space groups

Enantiomorphism

Enantiomorphous

Enantiomorphous group

Enantiomorphous helices

Enantiomorphous helices isotactic polymers

Enantiomorphous inorganic crystals

Enantiomorphous molecules

Enantiomorphous objects

Enantiomorphous pairs

Enantiomorphs

Enantiomorphs

Enantiomorphs achiral/chiral structures

Enantiomorphs and chirality

Enantiomorphs chiral point groups

Enantiomorphs defined

Enantiomorphs homochirality classes

Enantiomorphs resolution

Enantiomorphs, definition

Enantiomorphs, sweet

Helix enantiomorphs

Isomerism geometrical enantiomorphic

Optical Activity and Enantiomorphism

Optical activity enantiomorphism

Quartz enantiomorphism

Quartz, enantiomorphic

SUBJECTS enantiomorphism

Site enantiomorphic

Stereoisomerism enantiomorphs

Surfaces enantiomorphism

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