Reaction mechanisms lone pair reactions

A plausible reaction mechanism for this reaction was proposed by the authors. The Cu(i) carbene 182 generated from ethyl diazoacetate and the chiral Gu(i) complex can either react with another molecule of ethyl diazoacetate to form a mixture of diethyl maleate and fumarate 183, or with the imine lone pair to form a Gu(i)-complexed azomethine ylide... 

C X bond, but not from B because only the has such an orbital. If the intermediate is in conformation B, the OR may leave (if X has a lone-pair orbital in the proper position) rather than X. This factor is called stereoelectwnic control Of course, there is free rotation in acyclic intermediates, and many conformations are possible, but some are preferred, and cleavage reactions may take place faster than rotation, so stereoelectronic control can be a factor in some situations. Much evidence has been presented for this concept. More generally, the term stereoelectronic effects refers to any case in which orbital position requirements affect the course of a reaction. The backside attack in the Sn2 mechanism is an example of a stereoelectronic effect. 

Since activation of the N-H bond of PhNHj by Ru3(CO)i2 has been reported to take place under similar conditions [306], it has been proposed that the reaction mechanism involves (i) generation of an anUido ruthenium hydride, (ii) coordination of the alkyne, (iii) intramolecular nucleophilic attack of the nitrogen lone pair on the coordinated triple bond, and (iv) reductive ehmination of the enamine with regeneration of the active Ru(0) center [305]. 

The mechanism to be dicussed resembles that given by Weber [9] for the reaction of dimethylsilylene with protic substrates. Zwitterionic compounds, formed by interaction of the lone pair of the substrate with the vacant p orbital at silicon, are regarded as intermediates. 

The reactions of halogens and hydrogen halides with alkenes are electrophilic addition reactions. This means that the initial attack on the organic molecule is by an electron-deficient species that accepts a lone pair of electrons to form a covalent bond. This species is called an electrophile. In the case of the reaction with hydrogen bromide, the mechanism for the reaction is as shown. 

Although pathway 2 in the oxidation process (Scheme 2) may be considered analogous to mechanisms proposed for carbon hydroxylations catalyzed by cytochrome P-450, abstraction of an electron from the lone pair on nitrogen (pathway 1) would be a more likely first step in these types of reactions. It is reasonable to assume that the nature of substituents R, R2, and R3 would greatly influence the rate and path of reaction. The mechanistic possibilities in Scheme 2 are undoubtedly simplistic in their representation of the active oxygen species of cytochrome P-450 and are by no means comprehensive. However, these pathways do serve to illustrate.the role of radical substrate intermediates in cytochrome P-450-catalyzed reactions. More detailed analyses of mechanistic studies on these and other cytochrome P-450-mediated reactions can be found in recent reviews on the subject 49, 50, 60). 

Generally, ionic mechanisms will be favored for reactions of heteroatom-substituted dienylcarbene complexes, because of the stabiblization of charges by lone pairs. 

In the approach of Puddephatt et al., the P-phenyl-phosphonitocavitand 2 was obtained by the reaction of phenylphosphonous chloride on re-sorc[4]arene lb (1, R=CH2CH2C6H5) in presence of pyridine as base. The reaction is stereoselective and yielded the bowl-shaped molecule 2 with the four P-phenyl groups directed outwards and the four lone pairs directed inwards ini configuration) [45-49] (Scheme 6). Molecular mechanics calculations performed on the six possible isomers of 2, showed that the iiii isomer is preferred and the orientation of one phenyl group toward the macrocyclic cavity is probable iiio isomer), but two or more phenyl groups oriented inwards are highly unlikely [48]. 

A plausible mechanism for the formation of 4 is rationalized on the basis that photolysis of 3 results in [2-1-2] cyclization to thietane 4 and is subsequently followed by rearrangement to thiolactone 5 (Scheme 6). Ring opening of the initially formed thietane 4 leads to a zwitterion, which is facilitated by lone pair electrons of nitrogen and oxygen atoms, and nucleophilic reaction of the thiolate anion to carbonyl carbon gives 5. For the tricyclic thietane 4a, nucleophilic addition of the thiolate anion is difficult, and results in the formation of stable thietane 4a. 

Step 3 Forming a carbocation is difficult however, tertiary Ccirbocations, such as this one, can form as intermediates, or species that exist for a short time during the reaction. (See Figure 2-12.) The positive chcirge on the carbon makes this a strong electrophile that seeks a lone pair. In the final step of this mechanism, the carbocation accepts a lone pair from the chloride ion generated in the first step. The transfer is lone pair to bond. 

In the preceding mechanism, the carbocation was an intermediate (a species that exists for a short time during the reaction). The form of the intermediate is often essential to understanding the mechanism. The curved arrows help you in drawing the intermediate. Because you can use curved arrows in only three ways (bond to lone pair, bond to bond, and lone pair to bond), you have limited options for drawing intermediates. 

The Michael addition of nucleophiles to coumarins catalyzed by solid bases provides an interesting approach to the synthesis of 4-substituted 3,4-dihydrocumarins, because with the conventional Michael catalysts the alkaline hydrolysis of the 8-lactone predominates (Scheme 44). Results were obtained when the Michael addition of diethyl malonate to coumarin was catalyzed by the activated Ba(OH)2 292). An unusual 1,2-addition-elimination process at the C = 0 bond was observed. The mechanism of this reaction was explained on the basis of the microcrystalline structure of the catalyst. It was suggested that the rigid coumarin molecule interacts with the Ba ions through the lone-pair electrons of both oxygen atoms of the... 

---