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Aromatic Bonds Aromaticity

Log P calculation for quinidine with the atom contribution method according to Ghose and Crippen. R group connected to C X heteroatom = double bond aromatic bond aromatic single bond (e.g. C=N in pyrrole) subscripts give the hybridization state and superscripts the formal oxidization number. For the quinidine structure see Fig. 14.1. [Pg.373]

Ti-arene complexes Complexes in which an aromatic system is bonded to a metal through its r-electrons. Generally only applied to complexes of uncharged aromatic systems, e.g. [(CeHe)2Cr] but formally applied to any complex of an aromatic system, e.g. [(CjH5)2Fe] as a complex of (C5H3)". [Pg.41]

Bucherer reaction Bucherer discovered that the interconversion of 2-naphthol and 2-naphthylamine through the action of alkali and ammonia could be facilitated if the reaction was carried out in the presence of (HSO3]" at about 150 C. This reaction is exceptional for the ease with which an aromatic C —OH bond is broken. It is not of general application, it is probable that the reaction depends upon the addition of [HSO3]" to the normally unstable keto-form of 2-naphthol, and subsequent displacement of —OH by —NH2. [Pg.69]

Methods of producing B —C bonds include hydroboration, nucleophilic displacement at a boron atom in BX., (X = halogens or B(0R>3) by e.g. a Grignard reagent, and a psewiio-Friedel-Crafts reaction with an aromatic hydrocarbon, BX3, and AICI3. [Pg.289]

Asphaltenes are obtained in the laboratory by precipitation in normal heptane. Refer to the separation flow diagram in Figure 1.2. They comprise an accumulation of condensed polynuclear aromatic layers linked by saturated chains. A folding of the construction shows the aromatic layers to be in piles, whose cohesion is attributed to -it electrons from double bonds of the benzene ring. These are shiny black solids whose molecular weight can vary from 1000 to 100,000. [Pg.13]

For chemical processes, some examples are the elimination of aromatics by sulfonation, the elimination of olefins by bromine addition on the double bond (bromine number), the elimination of conjugated diolefins as in the case of the maleic anhydride value (MAV), and the extraction of bases or acids by contact with aqueous acidic or basic solutions. [Pg.26]

Correlations have been found between certain absorption patterns in the infrared and the concentrations of aromatic and paraffinic carbons given by the ndA/method (see article 3.1.3.). The absorptions at 1600 cm due to vibrations of valence electrons in carbon-carbon bonds in aromatic rings and at 720 cm (see the spectrum in Figure 3.8) due to paraffinic chain deformations are directly related to the aromatic and paraffinic carbon concentrations, respectively. )... [Pg.60]

The napthanes (C H2n), or cycloalkanes, are ring or cyclic saturated structures, such as cyclo-hexane (CgH 2) though rings of other sizes are also possible. An important series of cyclic structures is the arenes (or aromatics, so called because of their commonly fragrant odours), which contain carbon-carbon double bonds and are based on the benzene molecule. [Pg.92]

The immediate site of the adsorbent-adsorbate interaction is presumably that between adjacent atoms of the respective species. This is certainly true in chemisorption, where actual chemical bond formation is the rule, and is largely true in the case of physical adsorption, with the possible exception of multilayer formation, which can be viewed as a consequence of weak, long-range force helds. Another possible exception would be the case of molecules where some electron delocalization is present, as with aromatic ring systems. [Pg.591]

Wiliams D E 1965 Non-bonded potential parameters derived from crystalline aromatic hydrocarbons J. Chem. Phys. 45 3770... [Pg.216]

Bonds Single, double, triple, and aromatic (or conjugated) bonds are indicated by the symbols and " respectively single and aromatic bonds should be omitted. [Pg.28]

We will show here the classification procedure with a specific dataset [28]. A reaction center, the addition of a C-H bond to a C=C double bond, was chosen that comprised a variety of different reaction types such as Michael additions, Friedel-Crafts alkylation of aromatic compounds by alkenes, or photochemical reactions. We wanted to see whether these different reaction types can be discerned by this... [Pg.193]

The correction term in Eq. (9) shows that the basic assumption of additivity of the fragmental constants obviously does not hold true here. Correction has to be appHed, e.g., for structural features such as resonance interactions, condensation in aromatics or even hydrogen atoms bound to electronegative groups. Astonishingly, the correction applied for each feature is always a multiple of the constant Cu, which is therefore often called the magic constant . For example, the correction for a resonance interaction is +2 Cj, or per triple bond it is -1 A detailed treatment of the Ef system approach is given by Mannhold and Rekker [5]. [Pg.493]

The solubility of a compound is thus affected by many factors the state of the solute, the relative aromatic and aliphatic degree of the molecules, the size and shape of the molecules, the polarity of the molecule, steric effects, and the ability of some groups to participate in hydrogen bonding. In order to predict solubility accurately, all these factors correlated with solubility should be represented numerically by descriptors derived from the structure of the molecule or from experimental observations. [Pg.495]

An enhancement of the simple substructure approach is the Fragment Reduced to an Environment that is Limited (FREL) method introduced by Dubois et al. [7] With the FREL method several centers of the molecule are described, including their chemical environment. By taking the elements H, C, N, O, and halogens into account and combining all bond types (single, double, triple, aromatic), the authors found descriptors for 43 different FREL centers that can be used to characterize a molecule. [Pg.516]

Figure 10.3-38. An Indication of other speclRcatlon elements for a substructure query, For both the atom specifications and the bond specifications a vast list of attributes can be set (aromatic/ not aromatic, member of ring with n atoms, substituted, etc.). Figure 10.3-38. An Indication of other speclRcatlon elements for a substructure query, For both the atom specifications and the bond specifications a vast list of attributes can be set (aromatic/ not aromatic, member of ring with n atoms, substituted, etc.).
A con jugated sp - -sp --" single bond (for example, the bond joining the tw o phenyl rings of biphenyl, the central bond of butadiene, with delocali/ed aromatic bonds, or phenyl amine, where N-G bond is labeled aromatic and nitrogen is sp2 b h ybridi/ed) IS described by a two-fold barrier, V2=l() kcal/mol. [Pg.212]

See other pages where Aromatic Bonds Aromaticity is mentioned: [Pg.35]    [Pg.41]    [Pg.55]    [Pg.81]    [Pg.123]    [Pg.127]    [Pg.199]    [Pg.208]    [Pg.273]    [Pg.304]    [Pg.5]    [Pg.10]    [Pg.11]    [Pg.1449]    [Pg.2827]    [Pg.354]    [Pg.187]    [Pg.191]    [Pg.404]    [Pg.404]    [Pg.428]    [Pg.493]    [Pg.493]    [Pg.498]    [Pg.503]    [Pg.526]    [Pg.527]    [Pg.172]    [Pg.208]    [Pg.208]    [Pg.208]    [Pg.212]   
See also in sourсe #XX -- [ Pg.191 , Pg.214 , Pg.271 ]



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Addition of Aromatic C-H Bonds to Olefins

An aromatic C-F bond

Anisotropy of Bonds and Systems (other than Aromatic)

Aromatic Bonds Electron Rule

Aromatic C- N bond formation

Aromatic C-H Bonds

Aromatic C-H bond functionalisations

Aromatic C-Heteroatom Bond Formation

Aromatic C-N Bond Formation with Non-Amine Substrates and Ammonia Surrogates

Aromatic and heterocyclic double bonds

Aromatic bond

Aromatic bond activation

Aromatic bond localization

Aromatic bond-length

Aromatic carbon-halogen bond, cleavage

Aromatic carbon-hydrogen bonds

Aromatic carbon-nitrogen bond

Aromatic compounds bond lengths

Aromatic compounds bond polarity

Aromatic compounds bonds

Aromatic hydrocarbons double-bond addition

Aromatic hydrogen bond

Aromatic rings bond cleavage

Aromatic valence bond

Aromatic-halogen bond formation

Aromaticity bond orbital atomic charges

Aromaticity chemical bond interpretation

Aromatics n-bonded

Aromatization double bonds

Arylation of aromatic C-H bonds

Bond relocation, aromaticity

Bonding Aromatic ring association

Bonding aromatic compounds

Bonding in Aromatic Compounds

Bonding in Inorganic Aromatic Compounds

Bonding in aromatics

Borylation of aromatic C-H bonds

Catalyzed borylation of aliphatic and aromatic C-H bonds

Containing metal-oxygen bonds aromatic polyalcohols, carboxylic acids

Direct arylation of aromatic C-H bonds

Do Aromatics Form Hydrogen Bonds

Double bond additions carbon atom-aromatic compound reactivity

Double bonds aromatic hydrocarbons

Epoxidation aromatic double bond

Essential Single and Double Bonds General Rules for Aromaticity

Ferrocene, bonding electrophilic aromatic

Hydrogen Bonding-Mediated Self-assembly of Aromatic Supramolecular Duplexes

Hydrogen bonding aromatic oximes

Multicenter bond indices aromaticity

Multiple bonds and aromaticity

Organic molecule bonding aromatic hydrocarbons

Polymers Containing Aromatic C—H Bonds

Pyridine, aromaticity bond lengths

Silylation of Aromatic Carbon-Hydrogen Bonds

Silylation of aromatic C-H bonds

Strengths of the Bonds Formed between Free Radicals and Aromatic Rings

Valence-bond Isomers of Aromatic Compounds

Valence-bond method, aromatic reactivity

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