SN2-displacement

Relative Rate of Sn2 Displacement of 1-Biomobutane by Azide in Various Solvents ... 

Stereoelectronic control also plays a role in mechanistic stereoselectivity. One such case is the very fundamental 8 2 process which proceeds rigorously with inversion of configuration at carbon. Because of that intrinsic and predictable stereoselectivity, the C-C disconnective Sn2 displacement transform is very important even though it does not directly reduce the number of stereocenters, e.g. 153 => 154. 

Two different routes to PCs via bicyclo[3.1.0]hexane intermediates are shown. In route 1 stereo- and position-specific addition of dichloroketene to a bicyclo[3.1.0]hexene provided the framework for elaboration to prostanoids. Route 2 featured stereospecific internal cyclopropanation and stereospecific Sn2 displacement of carbon to establish the prostanoid nucleus. 

Deuteration at C-4 by Sn2 Displacement of the 6 -Chlorine in a A -Steroid with Lithium Aluminum Deuteride... 

Select bromide+tert-butyI chloride from the molecules on screen. This provides a series of frames describing the Sn2 displacement of chloride in rerr-butyl chloride by bromide. A bar appears at the bottom of the screen. 

The mechanism for the Wenker aziridine synthesis is very straightforward. As depicted by conversion 2—>3, the transformation is a simple case of intramolecular Sn2 displacement process, in which the sulfate ester is the leaving group. 

The syntheses were effected by selective mesylation of one or two hydroxyl groups and displacement of each mesyloxy group by an azido group, which was reduced to amino. Although attempted SN2 displacement of cyclohexane substituents is often unsuccessful, the powerfully nucleophilic azide ion is usually able to displace an alkylsulfonoxy group, and this route has been exploited in several recent cyclitol syntheses. 

The 1-mesyloxy intermediate (6) was similarly prepared via the equatorial monobenzoate, and it reacted with azide ion by a single SN2 displacement, since no anchimeric effect was possible here. The scyllo... 

Diethyl ether and other simple symmetrical ethers are prepared industrially by the sulfuric acid-catalyzed dehydration of alcohols. The reaction occurs by SN2 displacement of water from a protonated ethanol molecule by the oxygen atom of a second ethanol. Unfortunately, the method is limited to use with primary alcohols because secondary and tertiary alcohols dehydrate by an El mechanism to yield alkenes (Section 17.6). 

Both methods of nitrile synthesis—SN2 displacement by CN- on an alkyl halide and amide dehydration—are useful, but the synthesis from amides is more general because it is not limited by steric hindrance. 

Sn2 addition 413 Sn2 displacement 215 Sn2 lactone opening 412 ff. sodium bis(2-methoxyethoxy)-aluminium hydride see Red-Al sodium chlorite 516 - oxidation 772 sodium hypochlorite 550 f. sodium naphthalenide 739 f. sodium trimethoxyborohydride 390 SOMO 409... 

The earliest method developed for the preparation of nonracemic aziridine-2-car-boxylates was the cyclization of naturally occurring (3-hydroxy-a-amino acid derivatives (serine or threonine) [4]. The (3-hydroxy group is normally activated as a tosyl or mesyl group, which is ideal for an intramolecular SN2 displacement. The cyclization has been developed in both one-pot and stepwise fashion [4—9]. As an example, serine ester 3 (Scheme 3.2) was treated with tosyl chloride in the presence of triethylamine to afford aziridine-2-carboxylate 4 in 71% yield [9]. Cyclization of a-hydroxy- 3-amino esters to aziridine-2-carboxylates under similar conditions has also been described [10]. 

N-Acylaziridine-2-carboxylates readily rearrange to oxazolines under thennal, acidic, or nucleophilic conditions [91, 123-127]. Treatment of trans-aziridine-2-car-boxylate 176 (Scheme 3.63) with Nal in acetonitrile, for example, resulted in ring-expansion product 177 through the so-called Heine reaction. The reaction involves initial opening of the aziridine ring by iodide and subsequent oxazoline ring-closure by Sn2 displacement of the resultant iodide intermediate [127]. 

The synthesis of 10 features the SN2 displacement of the allylic acetate with migration of R2 from the ate complex6. Precursors 9 are prepared by the hydroboration of 3-acetoxy-l-alkynes that are available with very high enantiomeric purity via the asymmetric reduction of the corresponding l-alkyn-3-ones, and a substantial degree of asymmetric induction occurs in the conversion of 9 to 10. Best results, based on the enantioselectivity of reactions of 10 with aldehydes, are obtained when R2 is a bulky group such as isopinocampheyl (79 85 % ee)6. The yields of reactions of 10 with aldehydes are 62-76%. 

The selectivity decreases with increasing amide size. This may be due to steric hindrance which prevents the chiral ligand from approaching the reaction site or may reflect a change in the reaction mechanism going from an SN1 reaction (A-acylimine 2 as intermediate) to an SN2 displacement of benzotriazole11. 

Vinyloxirancs and vinyl acetals constitute a special subset of allylic electrophiles. The product of Sn2 displacement of vinyloxiranes is an allylic alcohol, while the SN2 product from vinyl acetals is a vinyl ether. 

Alkylallenes are obtained by the reaction of 1-ethynylcycloalkanol acetates with organocopper reagents, lithium dimethyl- and dibutylcuprates643 (see Section B.l). Even in the case of the presence of a substituent at the acetylenic terminus, SN2 displacement takes place, giving tetra-substituted allenes. Reaction of the steroidal 17-acetoxy-17-ethynyl derivative la shows that the... 

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