Double bonds, addition

For purely alicyclic compounds, the selection process proceeds successively until a decision is reached (a) the maximum number of substituents corresponding to the characteristic group cited earliest in Table 1.7, (b) the maximum number of double and triple bonds considered together, (c) the maximum length of the chain, and (d) the maximum number of double bonds. Additional criteria, if needed for complicated compounds, are given in the lUPAC nomenclature rules. 

Some details of the chain-initiation step have been elucidated. With an oxygen radical-initiator such as the /-butoxyl radical, both double bond addition and hydrogen abstraction are observed. Hydrogen abstraction is observed at the ester alkyl group of methyl acrylate. Double bond addition occurs in both a head-to-head and a head-to-tail manner (80). 

In order to locate items of interest in the book, the subject index lists, in addition to chemical operations, types of compounds rather than specific compounds (with a few exceptions). If, for example, readers do not find what they are looking for under the entry fluoroolefins , they may try olefins , double bonds, additions of , etc. 

Addition reactions — The fullerenes Ceo and C70 react as electron-poor olefins with fairly localized double bonds. Addition occurs preferentially at a double bond common to two annelated 6-membered rings (a 6 6 bond) and a second addition, when it occurs is generally in the opposite hemisphere. The first characteriz-able mono adduct was [C6oOs04(NC5H4Bu )2]. formed by reacting Cgo with an excess of OSO4 in 4-butylpyridine. The structure is shown in... 

Naphthalene and other polycyclic aromatic hydrocarbons show many of the chemical properties associated with aromaticity. Thus, measurement of its heat of hydrogenation shows an aromatic stabilization energy of approximately 250 kj/mol (60 kcal/mol). Furthermore, naphthalene reacts slowly with electrophiles such as Br2 to give substitution products rather than double-bond addition products. 

Radicals can be classified according to their tendency to give aromatic substitution, abstraction, double bond addition, or (3-scission and further classified in terms of the specificity of these reactions (see 3.4). With this knowledge, it should be possible to choose an initiator according to its suitability for use with a given monomer or monomer system so as to avoid the formation of undesirable end groups or, alternatively, to achieve a desired functionality. 

The relative amounts of double bond addition, hydrogen abstraction and 13-scission observed are dependent on the reactivity and concentration of the particular monomer(s) employed and the reaction conditions. Higher reaction temperatures are reported to favor abstraction over addition in the reaction of t-butoxy radicals with AMS413 and cyclopentadiene 417 However, the opposite trend is seen with isobutylene.2 1 24... 

Isopropoxycarbonyloxy radicals undergo facile reaction with aromatic substrates (e.g. toluene) by reversible aromatic substitution. 94 Isopropoxycarbonyloxy radicals react with S to give ring substitution (ca 1%) as well as the expected double bond addition.40 ... 

The onward metabohsm of succinate, leading to the regeneration of oxaloacetate, is the same sequence of chemical reactions as occurs in the P-oxidation of fatty acids dehydrogenation to form a carbon-carbon double bond, addition of water to form a hydroxyl group, and a hirther dehydrogenation to yield the oxo- group of oxaloacetate. 

Repeating unit isomerization is similar in several respects to isomerization polymerization (26,27). Isomerization polymerization may be defined as a process whereby a monomer of structure A is converted to a polymer of repeating unit structure B, wherein the conversion of A to B represents a structural change which is not a simple ring opening or double bond addition ... 

Although the high reactivity of metal-chalcogen double bonds of isolated heavy ketones is somewhat suppressed by the steric protecting groups, Tbt-substituted heavy ketones allow the examination of their intermolecular reactions with relatively small substrates. The most important feature in the reactivity of a carbonyl functionality is reversibility in reactions across its carbon-oxygen double bond (addition-elimination mechanism via a tetracoordinate intermediate) as is observed, for example, in reactions with water and alcohols. The energetic basis... 

Intermolecular Cycloaddition at the C=C Double Bond Addition at the C=C double bond is the main type of 1,3-cycloaddition reactions of nitrile oxides. The topic was treated in detail in Reference 157. Several reviews appeared, which are devoted to problems of regio- and stereoselectivity of cycloaddition reactions of nitrile oxides with alkenes. Two of them deal with both inter- and intramolecular reactions (158, 159). Important information on regio-and stereochemistry of intermolecular 1,3-dipolar cycloaddition of nitrile oxides to alkenes was summarized in Reference 160. 

Double-bond additions may proceed according to three transition state models A, B and C. 

In the following reactions, the predictive power of these models for various types of double-bond additions is demonstrated42 " 31. 

The same models as for intermolccular processes are applied for intramolecular diastereoface differentiating double-bond additions. However, there are some advantages in the intramolecular version. Firstly, the entropy factor lowers the barrier of activation and allows reactions to proceed at lower temperatures, which increases the selectivity. Secondly, the cyclic transition states introduce the elements of ring strain and transannular interactions, which lead to enhanced differences between two diastereomorphous geometries. Both of these factors cooperate to increase the selectivity of the intramolecular reaction. For example, halolactonization, by definition, is an intramolecular process. 

In analogy with carbenes, atomic carbon reacts with alkenes by double-bond addition (DBA) to give cyclopropylidenes such as 19, which undergo the known ring... 

C-H Insertion versus Double-Bond Addition in the Reaction of Carbon with Aromatics. The factors that determine if C atoms react with an aromatic by C—H insertion or DBA are not yet understood. Benzene and substituted benzenes are postulated to react by C—H insertion although detailed labeling studies have only been carried out in benzene, toluene, and ferf-butylbenzene. No C—H insertion is observed in the reaction of carbon with 71, while C—H insertion is a minor pathway when carbon reacts with 76 and 87. 

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