Heteroatom substituted alkene

Many chiral diphosphine ligands have been evaluated with regard to inducing enantioselectivity in the course of the hydroformylation reaction [25,26]. However, a real breakthrough occurred in 1993 with the discovery of the BI-NAPHOS ligand by Takaya and Nozaki [65]. This was the first efficient and rather general catalyst for the enantioselective hydroformylation of several classes of alkenes, such as aryl alkenes, 1-heteroatom-functionalized alkenes, and substituted 1,3-dienes, and is still a benchmark in this area [66,67]. But still a major problem in this field is the simultaneous control of enantio-... 

The major problem remains control of regioselectivity in favor of the branched regioisomer. While aryl alkenes as well as heteroatom-substituted alkenes favor the chiral branched isomer, for aliphatic alkenes such an intrinsic element of regiocontrol is not available. As a matter of fact branched-selective and asymmetric hydroformylation of aliphatic alkenes stands as an unsolved problem. In this respect regio- and enantioselective hydroformy-... 

Dipolarophiles D12. Heteroatom substituted alkenes of general formula D12 have been sparingly used as dipolarophiles when compared to vinyl ethers Dll (see Fig. 2.33). Comparative studies between common heating and microwave... 

Heteroatom-substituted carbene complexes are less electrophilic than the corresponding methylene, dialkylcarbene, or diarylcarbene complexes. For this reason cyclopropanation of electron-rich alkenes with the former does not proceed as readily as with the latter. Usually high reaction temperatures are necessary, with radical scavengers being used to supress side-reactions (Table 2.16). Also acceptor-substituted alkenes can be cyclopropanated by Fischer-type carbene complexes, but with this type of substrate also heating is generally required. 

Non-heteroatom-substituted vinylcarbene complexes are readily available from alkynes and Fischer-type carbene complexes. These intermediates can undergo the inter- or intramolecular cyclopropanation reactions of non-activated alkenes. Cyclopropanation of 1,3-butadienes with these intermediates also leads to the formation of cycloheptadienes (Entry 4, Table 2.24). 

J Non-Heteroatom-Substituted Carbene Complexes Table 3.21. Preparation of alkenes and dienes by cross metathesis. 

The reaction of heteroatom-substituted alkenes with electrophilic carbene complexes can lead to the formation of highly reactive, donor-acceptor-substituted cyclopropanes. This type of cyclopropane usually undergoes ring fission and rearrangement reactions under milder conditions than do unsubstituted cyclopropanes (Figure 4.22). 

Under optimized conditions, cycloisomerizations of a number of functionalized hept-l-en-6-ynes took place in good-to-excellent yields (Table 9.3). Heteroatom substitution was tolerated both within the tether and on its periphery. Alkynyl silanes and selenides underwent rearrangement to provide cyclized products in moderate yield (entries 6 and 7). One example of seven-membered ring formation was reported (entry 5). Surprisingly, though, substitution was not tolerated on the alkene moiety of the reacting enyne. The authors surmize that steric congestion retards the desired [2 + 2]-cycloaddition reaction to the point that side reactions, such as alkyne dimerization, become dominant. 

Alkanes can be prepared by the addition of carbon radicals to C=C double bonds (Figure 5.4). The highest yields are usually obtained when electron-rich radicals (e.g. alkyl radicals or heteroatom-substituted radicals) add to acceptor-substituted alkenes, or when electron-poor radicals add to electron-rich double bonds. These reactions have also been performed on solid phase, and polystyrene-based supports seem to be particularly well suited for radical-mediated processes [39,40]. 

Most synthetically useful radical addition reactions pair nucleophilic radicals with electron poor alkenes. In this pairing, the most important FMO interaction is that of the SOMO of the radical with the LUMO of the alkene.36 Thus, many radicals are nucleophilic (despite being electron deficient) because they have relatively high-lying SOMOs. Several important classes of nucleophilic radicals are shown in Scheme IS. These include heteroatom-substituted radicals, vinyl, aryl and acyl radicals, and most importantly, alkyl radicals. 

Intramolecular cyclopropanations of pendant alkenes are more favorable. Heteroatom-substituted 2-aza- and 2-oxabicyclo[3.1.0]hexanes, together with 2-oxabicyclo[4.1.0] heptanes, can be prepared from chromium and tungsten Fischer carbenes having a tethered alkene chain. An interesting carbene formation via a cationic alkylidene intermediate, nucleophilic addition (see Nucleophilic Addition Rules for Predicting Direction), and intramolecular cyclopropanation is shown in Scheme 59. An intramolecular cyclopropanation via reaction of alkenyl Fischer carbene complex (28) andpropyne was used in a formal synthesis of carabrone (Scheme 60). 

The cycloaddition of dibcnzoyldiazene and phenyl- or heteroatom-substituted cyclic and acyclic alkenes gives oxadiazines15-18. The oxadiazine 20 obtained from 1 -(1 -piperidinyl)- or -4-morpholinyl)cyclohexene has a cis ring junction (X-ray analysis)17. 

The next selectivity issue, exo/endo preferences, can be predicted for both the ortho and meta modes of cycloaddition on the basis of secondly orbital interactions (FMO treatment) and by electrostatic considerations involving polarized species (54) and (27). In general, intermolecular reactions with simple al-kenes proceed with endo selectivity. Heteroatom-substituted or polarized alkenes (equation 11) give exolendo mixtures, whose composition can be explained by electrostatic considerations. Intramolecular cycloadditions of simple alkenes and arenes joined by a three-atom tether generally proceed with high exo selectivity due in part to orbital alignment effects. In all cases, alkene geometry is preserved, except for sterically encumbered alkenes, in which case excitation transfer from the arene to the alkene can occur. 

Several examples are presented in Table 15 which indicate that a-heteroatom substitution is compatible with this reagent. The tremendous advantage of the trifluoroethyl phosphonate reagent is the selective formation of (Z>alkene with aromatic aldehydes, while the trimethyl phosphonate gives the normal selectivity. 

Because of the variety of phenyl sulfides, numerous precursors for organolithiums are available. Primary alkylphenyl sulfides are available from nucleophilic displacements of halides or addition of CgHjSH to terminal alkenes so that the sulfide hydrogen goes to the carbon with least hydrogens. Secondary and tertiary alkylphenyl sulfides are available from addition of CgHjSH to alkenes in the reverse manner . Alkoxyphenyl sulfides can be prepared also". Other heteroatom-substituted phenyl sulfides, including phenylthioacetals and ketene phenylthioacetals, are also available. 

Bach, T. The Paterno-Buchi reaction of 3-heteroatom-substituted alkenes as a stereoselective entry to polyfunctional cyclic and acyclic molecules. Liebigs Ann. Chem. 1997,1627-1634. 

Common error alert A nucleophilic alkene always reacts with an electrophile such that the C less able to be electron-deficient makes the new bond. In alkenes directly substituted with lone-pair-bearing heteroatoms (enolates, enamines, enols, enol ethers), the /3-carbon (not attached to heteroatom) is nucleophilic, and the a-carbon (attached to heteroatom) is not. In alkenes substituted only with alkyl groups,... 

A number of heteroatom-substituted dilakylaluminum compounds (R2AICH2-X) can undergo apparent a-, aP-, or ay-eliminations. The apparent a-elimination, when halomethylaluminum compounds cyclopropanate alkenes, is actually a combination of carboalumination and elimination [Eq. (6.87)]. Such eliminations involve hypercarbon intermediates or transition states. 

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