Alkene complexes strain

Diboration of alkene is catalyzed by Pt(0),42,48-51 Rh(i),52-57 Au(i),52 and Ag(i)58 complexes. Phosphine-free platinum complexes such as Pt(dba)2 and Pt(cod)2 are efficient catalysts for diboration of alkene, whereas those with phosphine ligands show much lower catalytic activities (Equations (3) and (4)).48,49 A PtCl2(cod) complex, which may be readily reduced to Pt(0) species with diboron, also catalyzes the addition of bis(catecholato)diboron to alkenes.42 Platinum-catalyzed diboration has so far been limited to terminal alkenes and strained cyclic alkenes. 

Yttrocene complexes catalyze the cascade cyclization/hydrosilylation of trienes to form saturated silylated bicyclic compounds.For example, reaction of the 4-silyloxy-4-vinyl-l,6-hexadiene 69 and phenylsilane catalyzed by Gp 2YMe(THF) at room temperature for 1 h followed by oxidation of crude 70a gave [3.3.0]bicyclic diol 70b in 73% yield over two steps as a single diastereomer (Scheme 18). Selective conversion of 69 to 70a presumably requires initial 1,2-hydrometallation of one of the less-hindered G=G bonds to form alkylyttrium alkene complex II (Scheme 18). Selective S-exo carbometallation of II in preference to -exo carbometallation would form cyclopentyl-methylyttrium complex III (Scheme 18). Gyclization of III via a chairlike transition state would form the strained /r< /75 -fused alkylyttrium complex IIIl, which could undergo silylation to form 70a. 

It appears likely that transient metallacyclobutanes are involved in a variety of organic reactions which are catalyzed by transition metal complexes. Thus, cycloadditions of activated alkenes to strained hydrocarbons such as quadricyclane and bicyclo[2.1.0]pentane are catalyzed by complexes such as Ni(CH2=CHCN)2 and probably involve initial formation of a nickelacyclobutane (Scheme 2) (79MI12200). The nature of the organometallic intermediates in related metal-catalyzed rearrangements (72JA7757) and retro-cyclo-addition reactions (76JA6057) of cyclopropanoid hydrocarbons, e.g. bicyclo[n.l.O]alkanes, has been discussed. 

In carbene complexes which lack /3-hydrogens, for example (48 X = H, Y = t-Bu), alkyl migration can occur to afford trisubstituted alkene complexes (66). When this involves a polycyclic hydrocarbon, the result is a strained bridgehead alkene complex (67). ... 

The norbornene ligand is unique in yielding more stable homoleptie alkene complexes, apparently because the strain energy in the C=C bond allows stronger ti-M interactions. 

Alkene and alkyne r-complexes see Alkene Complexes and Alkyne Complexes are known both for Au and Au. They are prepared at low temperature from AuCl or AuCls with an excess of the alkene or alkyne in the absence of any other potential donor molecules. The products, for example, of the types (MeCH=CHMe)AuCl and MeC=CMe-(AuCl3)2, are generally of low stability, and the complexation is reversible in a vacuum or on heating. Representative examples have recently been structurally characterized.Strained cyclic alkenes and alkynes give the most stable products. Multiple coordination of monoalkenes or of dialkenes (like butadiene) is known, but information about the products is limited. Alkene coordination to neutral gold atoms has been studied by matrix-isolation techniques at very low temperature. The adduct (C2H4)Au appears to be stable only below 40 K. 

Copper(i) triflate, CuSOsF, is an efficient catalyst for the photodimerization of norbornene. The proposed mechanism of this reaction (Scheme 3), which is supported by quantum-yield studies, involves photoexcitation of a 2 1 alkene-CuSOsF complex followed by unimolecular collapse to products. An alternative mechanism involving photoexcitation of a 1 1 copper(i)-alkene complex and a subsequent termolecular interaction with two ground-state alkenes to give the dimer, a mechanism proposed for the photodimerization of norbomene-catalysed by copper(i) halides, is not consistent with the present studies. Photodimerizations catalysed by CuCl have only been observed with strained cycloalkenes. However, CuSOgF is an efficient catalyst for the photodimerization of simple alkenes e.g. cyclopentene. 

The resulting carbene complex 41b bears a hetero substituent and shows activity in the ring-opening/cross metathesis of strained bicyclic alkenes and... 

The phosphine-based platinum(O) catalysts do not catalyze the diboration of alkenes because of the high coordination ability of phosphine over the alkene double bond, but platinum(O) complexes without a phosphine ligand such as Pt(dba)2 [128] and Pt(cod)2 [129] are an excellent catalyst allowing the alkene insertion into the B-Pt bond under mild conditions (Scheme 1-30). The diboration of aliphatic and aromatic terminal alkenes takes place smoothly at 50°C or even at room temperature. The reaction is significantly slow for disubstituted alkenes and cyclic alkenes, but cyclic alkenes having an internal strain afford ds-diboration products in high... 

As invented by Wender,196,197 a variant of the second transformation can take place if the alkene partner is substituted by a participating group such as a strained cyclopropyl or a cyclobutanone (in the case of a 1,6-diene).198 The whole process, which mainly relies on the use of rhodium or ruthenium complexes,1 9 results in the formal... 

Addition of distannane to alkenes has been achieved only with strained cyclopropenes (Equation (60)).158 3,3-Disubstituted cyclopropenes undergo highly face-selective distannation in the presence of the palladium-isocyanide complex to afford m-adducts. 

In entries 10-13 (Table 21.8) of trisubstituted alkenes, very high diastereo-selectivity is realized by the use of a cationic rhodium catalyst under high hydrogen pressure, and the 1,3-syn- or 1,3-anti-configuration naturally corresponds to the ( )- or (Z)-geometry of the trisubstituted olefin unit [48, 49]. The facial selectivity is rationalized to be controlled by the A(l,3)-allylic strain at the intermediary complex stage (Scheme 21.2) [48]. 

The study of alkene insertions in complexes containing diphosphine ligands turned out to be more complicated than the study of the CO insertion reactions [13], When one attempts to carry out insertion reactions on acetylpalladium complexes decarbonylation takes place. When the reaction is carried out under a pressure of CO the observed rate of alkene insertion depends on the CO pressure due to the competition between CO and ethene coordination. Also, after insertion of the alkene into the acetyl species (3-elimination occurs, except for norbomene or norbomadiene as the alkene. In this instance, as was already reported by Sen [8,27] a syn addition takes place and in this strained skeleton no (3-elimination can take place. Therefore most studies on the alkene insertion and isolation of the intermediates concern the insertion of norbomenes [21,32], The main product observed for norbomene insertion into an acetyl palladium bond is the exo species (see Figure 12.8). 

Strain and steric properties of the alkenes determine the rate of insertion. The carbomethoxy complex (dppp)PdC(0)OCH3+ turned out to be less reactive than the corresponding acetyl-palladium (dppp)PdC(0)CH3+, which was ascribed to the higher nucleophilicity of the acetyl group as compared to the carbomethoxy group. 

One special case of cross metathesis is ring-opening cross metathesis. When strained, cyclic alkenes (but not cyclopropenes [818]) are treated with a catalytically active carbene complex in the presence of an alkene, no ROMP but only the formation of monomeric cross-metathesis product is observed [818,937], The reaction, which works best with terminal alkenes, must be interrupted when the strained cycloalkene is consumed, to avoid further equilibration. As illustrated by the examples in Table 3.22, high yields and regioselectivities can be achieved with this interesting methodology. 

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