Nucleophilicity influencing factors

At this point we consider some general relationships concerning the reactivity of carbonyl compounds toward addition of nucleophiles. Several factors influence the overall rate of a reaction under various conditions. Among the cmcial factors are (1) structural features of the carbonyl compound (2) the role of protons or other Lewis acids in activating the carbonyl group toward nucleophilic attack (3) the reactivity of the nucleophilic species and its influence on subsequent steps and (4) the stability of the tetrahedral intermediate and the extent to which it proceeds to product rather than reverting to starting material. 

Of course, these schemes indicate only that the overall reactions may be classified as nucleophilic 1,3-substitutions and, in the last case, as electrophilic 1,3-substitut ions. The reactions often proceed only in the presence of catalytic or stoichiometric amounts of transition metal salts, while in their absence 1,1--substitutions or other processes are observed. The 1,1-substitutions are also catalyzed by salts of transition metals, and it is not yet well understood, which factors influence the 1,1 to 1,3-ratio. In a number of 1,3-Substitutions there is... 

Many properties have an influence on nucleophilicity. Those considered to be most significant are (1) the solvation energy of the nucleophile (2) the strength of the bond being formed to carbon (3) the size of the nucleophile (4) flie electronegativity of the attacking atom and (5) the polarizability of the attacking atom. Let us consider how each of these factors affects nucleophilicity ... 

Factors that affect the rate-determining step (171 172) will influence the overall rate of reaction. A stronger nucleophile, such as hydrazine, is certainly more efficient than hydroxide, but no studies have been reported on the alternative variation of the electrophilicity of the 4-carbonyl group. Ring-opening may occur at either the 3 4.35,91,136,136 qj. 1 2-bouds in pyridopyrimidine-2,4(lH,-... 

Addition of trimethylaluminum to norcamphor (3), regardless of the stoichiometry of the reactants, leads to a mixture of the diastereomeric alcohols in a ratio of 95 5 also in favor of the erafo-alcohol6. Examination of the norcamphor model indicates that endo attack is sterical-ly more hindered than exo attack. However, steric interaction may not fully account for the exceptionally high exo selectivity. On the other hand, no severe torsional strain is involved if the nucleophile approaches the carbonyl group from the exo side, however, a nucleophile approaching from the endo side encounters torsional strain between the incipient bond and the C-l to C-6 carbon-carbon bond. Thus, in the case of norcamphor, steric and stereoelectronic factors reinforce each other, resulting in a strong directional influence for exo attack. 

With a-alkyl-substituted chiral carbonyl compounds bearing an alkoxy group in the -position, the diastereoselectivity of nucleophilic addition reactions is influenced not only by steric factors, which can be described by the models of Cram and Felkin (see Section 1.3.1.1.), but also by a possible coordination of the nucleophile counterion with the /J-oxygen atom. Thus, coordination of the metal cation with the carbonyl oxygen and the /J-alkoxy substituent leads to a chelated transition state 1 which implies attack of the nucleophile from the least hindered side, opposite to the pseudoequatorial substituent R1. Therefore, the anb-diastereomer 2 should be formed in excess. With respect to the stereogenic center in the a-position, the predominant formation of the anft-diastereomer means that anti-Cram selectivity has occurred. 

Compared to a bromonium ion, the C-S bonds are stronger and the TS for nucleophilic addition is reached later. This is especially true for the sulfurane structures. Steric interactions that influence access by the nucleophile are a more important factor in determining the direction of addition. For reactions involving phenylsulfenyl chloride or methylsulfenyl chloride, the intermediate is a fairly stable species and ease of approach by the nucleophile is the major factor in determining the direction of ring opening. In these cases, the product has the anti-Markovnikov orientation.62... 

Nucleophilic Trapping of Radical Cations. To investigate some of the properties of Mh radical cations these intermediates have been generated in two one-electron oxidant systems. The first contains iodine as oxidant and pyridine as nucleophile and solvent (8-10), while the second contains Mn(0Ac) in acetic acid (10,11). Studies with a number of PAH indicate that the formation of pyridinium-PAH or acetoxy-PAH by one-electron oxidation with Mn(0Ac)3 or iodine, respectively, is related to the ionization potential (IP) of the PAH. For PAH with relatively high IP, such as phenanthrene, chrysene, 5-methyl chrysene and dibenz[a,h]anthracene, no reaction occurs with these two oxidant systems. Another important factor influencing the specific reactivity of PAH radical cations with nucleophiles is localization of the positive charge at one or a few carbon atoms in the radical cation. 

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