Alkenes geometry

The Peterson oleflnation presents a valuable alternative to the Wittig reaction. It has the advantage to allow for a simple control of the alkene geometry. Its applicability in synthesis depends on the availability of the required silanes.2... 

The adducts derived from catechol borane are hydrolyzed by water to vinylboronic acids. These materials are useful intermediates for the preparation of terminal vinyl iodides. Since the hydroboration is a syn addition and the iodinolysis occurs with retention of the alkene geometry, the iodides have the -configuration.214... 

The effects of the allylic substituent, the alkene geometry, and the diene substitution as well as the influence of resident stereogenic centers incorporated in the tether connecting the 1,3-diene and the alkene subunits were totally investigated. This process has been applied to the reactions of more elaborated systems including heterocyclic structures,367 and the total synthesis of (—)-gibboside.368... 

Beyond palladium, it has recently been shown that isoelectronic metal complexes based on nickel and platinum are active catalysts for diyne reductive cyclization. While the stoichiometric reaction of nickel(O) complexes with non-conjugated diynes represents a robust area of research,8 only one example of nickel-catalyzed diyne reductive cyclization, which involves the hydrosilylative cyclization of 1,7-diynes to afford 1,2-dialkylidenecyclohexanes appears in the literature.7 The reductive cyclization of unsubstituted 1,7-diyne 53a illustrates the ability of this catalyst system to deliver cyclic Z-vinylsilanes in good yield with excellent control of alkene geometry. Cationic platinum catalysts, generated in situ from (phen)Pt(Me)2 and B(C6F5)3, are also excellent catalysts for highly Z-selective reductive cyclization of 1,6-diynes, as demonstrated by the cyclization of 1,6-diyne 54a.72 The related platinum bis(imine) complex [PhN=C(Me)C(Me)N=Ph]2Pt(Me)2 also catalyzes diyne hydrosilylation-cyclization (Scheme 35).72a... 

Insertion of carbon monoxide into Csp2—Zr bonds occurs readily at ambient temperatures or below to produce a,(5-unsaturated, reactive acyl zirconocene derivatives [27—29]. Early work by Schwartz demonstrated the potential of such intermediates in synthesis [5d], as they are highly susceptible to further conversions to a variety of carbonyl compounds depending upon manipulation. More recently, Huang has shown that HC1 converts 16 to an enal, that addition of a diaryl diselenide leads to selenoesters, and that exposure to a sulfenyl chloride gives thioesters (Scheme 4.11) [27,28]. All are obtained with (F)-stereochemistry, indicative of CO insertion with the expected retention of alkene geometry. 

A corollary to the above argument is that enantioselectivities depend on alkene geometry. Indeed, isomeric enolsilanes provide enantiomeric products. Because obtaining enolsilanes such as 344 in high isomeric purity is difficult, enantioselectivities with these nucleophiles are reflective, Eqs. 214 and 215. Pyrrole-derived enolsilanes are accessible in very high isomeric purity (>99 1) thus providing a convenient solution to this problem. Their use in the catalytic amination reaction provides access to a-hydrazino acid derivatives in high enantioselectivity. 

Extensive 13C and 81P n.m.r. studies have been reported for phosphine oxides and selenides, and the inversion-recovery technique has been used to establish 2J and ZJ values for 18C-31P coupling.52 Shift reagents have been used to establish alkene geometry in the oxides (61).53 Coupling and shift data have been published for the arylphosphine derivatives (62).54... 

Scheme 6.40. Influence of alkene geometry on stereoselectivity of allylic substitution of mesylates 189 and 192 with boron trifluoride-modified lower order cyanocuprate reagents.

In addition to insertions into polar X-H bonds by means of ylide intermediates, carbe-noids are capable of inserting into nonpolar bonds such as Si-H and C-H. The Si-H insertion by vinylcarbenoids has been developed as a novel method for the synthesis of allylsilanes 166 and 167 of defined geometry as illustrated in Eqs. (17) and (18) [28]. The alkene geometry of the vinyldiazoacetate is not altered during carbenoid formation or the subsequent Si-H insertion. 

The acyclic precursor is an oc, 3-unsaturated amido aldehyde that was condensed with iV-methylhydroxylamine to generate the nitrone ( )-48, which then underwent a spontaneous cycloaddition with the alkene to afford the 5,5-ring system of the isoxazolidinyl lactam 47. The observed product arises via the ( )-nitrone transition state A [or the (Z)-nitrone equivalent] in which the position of the benzyl group ot to the nitrone effectively controls the two adjacent stereocenters while a third stereocenter is predicted from the alkene geometry. Both transition states maintain the benzyl auxiliary in an equatorial position and thus avoid the unfavorable 1,3-diaxial interaction with the nitrone methyl or oxygen found in transition state B. Semiempirical PM3 calculations confirm the extra stability, predicting exclusive formation of the observed product 47. Related cycloadducts from the intramolecular reaction of nitrones containing ester- rather than amide-tethered alkene functionality are also known (83-85). 

This indicates no evidence of stereorandomization about the carbon—carbon double bond. It means that 74 cleaves in a concerted fashion to yield syn and anti zwitter-ions produced in different amounts depending on the alkene geometry. The stereo-isomeric zwitterions remain attached to each other like an ion pair and recombine stereoselectively with aldehydes. The subtle nature of ozonation, however, may be illustrated by the observation that ozonide formation may be nonconcerted under... 

The preservation of alkene geometry in these concerted cvcloaddi-tions implies a mode of reaction in which, for each alkene unit, the two new bonds are formed to the same face of the Ji-bond. This mode is called suprafacial-suprafacial cydoaddition, and is one of... 

The Lewis acid catalyzed conjugate addition of allylsilanes (140) to (142) and allylstannanes (154) and (155) to ot,0-enones, described by Sakurai,68a,68b is highly efficient and experimentally simple in contrast to the allylcuprate additions. Various substituents can be incorporated into the allylsilanes (allylstannanes), e.g. alkoxy, alkoxycarbonyl and halogen, some of which are incompatible with cuprate reagents 69 In addition, Heathcock and Yamamoto report that diastereoselectivity is correlated to the alkene geometry of both the allylmetals and the acceptor units for example, allylation of ( )-enones (143) and (146) affords predominantly the syn adducts (144) and (147), while (Z)-enone (149) gives predominantly the anti adduct (150 Scheme 25).680 On the other hand, with cyclohexen-2-one the (Z)-silane (141) affords predominantly the threo adduct (152), while (142) affords erythro adduct (ISS).686 The more reactive allylstannanes (154) and (155) also afford similar diastereoselectivity.68e,f... 

Although cobalt catalysts have been rarely used in cyclopropanation reactions, Nakamura and coworkers2 1 have developed the camphor-based complex (35) as a useful asymmetric catalyst, as shown in a typical example in equation (16). High yields were obtained with dienes and styrenes but cyclopropanation did not occur with simple alkenes. Studies with cu-ife-styrene showed that, unlike other catalytic systems, the reaction was not stereospecific with respect to alkene geometry. 

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