Vinyl carbene complex

The reaction course is shown in Scheme 4. Enyne 12 reacts with 2 to give vinyl carbene complex 17, which is in a state of equilibrium with vinyl ketene complex 21. [2+2] Cycloaddition of the ketene moiety and alkene part in 21 gives cyclob-utanone 22. On the other hand, the vinyl carbene complex 17 reacts with the alkene intramolecularly to produce metalacyclobutane 18. From metalacyclob-utane 18, reductive elimination occurs to give cyclopropane derivative 23. Ret-... 

In addition to the ring opening of cyclopropenes noted above, vinylketene complexes 103 have been prepared by (1) ligand initiated carbonyl insertion of vinyl carbene complexes 104 and (2) benzoylation of ,/3-unsaturalcd acyl ferrates 105 (Scheme 20)114. X-ray diffraction analysis of these vinylketene complexes indicates that the structure may be best represented as a hybrid between an /j4-dicnc type complex (103) and an jj3-allyl r/1 acyl complex (106). The Fe-Cl distance (ca 1.92 A) is shorter than the Fe-C2, Fe-C3, or Fe-C4 distances (ca 2.1-2.2 A)113a-C. In addition, the C—C—O ketene array is not linear (bend angle ca 135°). 

Aryl(dialkylamino)carbene chromium complexes do not yield aminonaphthols upon treatment with alkynes, but form indene derivatives. Vinyl(dialkylamino)car-bene complexes, however, react with alkynes to yield aminophenols as the main products if solvents of low nucleophilicity are used [335]. (2-Amino-1-vinyl)carbene complexes do not undergo benzannulation when treated with alkynes, but form cyclopentadienes or heterocycles instead [251]. 

Experimental Procedure 2.2.8. [4 + 3] Cycloaddition of a Chromium Vinyl-carbene Complex to a 1-Azadiene rra/w-4-(2-Furyl)-2-methoxy-5-methyl-4,5-dihydro-3H-azepine... 

The rearrangement exhibits some stereochemical preference for c/s-vinyl carbene complex (with respect to the metal) compared to the //ww-isomer. Thus, 2-methyl-2-m-vinyl cyclopropyl (methoxy) carbene chromium pentacarbonyl rearranges to 5-methyl-5-vinyl-2-methoxycyclopentenone approximately 4 times faster (THF, 52 °Q than the trans-isomer, which in turn rearranges faster than phenyl derivatives. This suggests that vinyl complexes undergo initial Cope-type rearrangement to form metallacycloheptadienes, which then rearrange to jt-allyl complexes. Subsequent CO insertion and reductive elimination leads to the vinylcyclopentenones (equation 89)150. 

The intermediacy of a metallacyclobutene is proposed upon reaction of the diphenylcy-clopropenone dimer spirolactone with CpCo(CO)2, ultimately yielding a >j4-vinylketene complex (equation 23 l)295a. Unlike the analogous iron complex (Section IV.B.2.a), no vinyl carbene complex was observed, and hence formation of the metallacyclobutene seems to be more likely. 

Casey and coworicers have shown that ketone etiolates add efficiently to a,3-unsaturated vinyl carbene complexes (164), irrespective of 3,3-disubstitution on the complex or high substitution on the enol-ate 133 thus, contiguous 3 and y quaternary centers are easily assembled. When coupled with the ease of release of the carbene ligand from the complexes by either oxidation to the ester functionality1331 or elimination to the corresponding enol ether,133 the vinyl carbene complexes are synthetic equivalents for a,3-unsaturated esters or a,3-unsaturated aldehydes, respectively (Scheme 63). 

Insertion of the alkyne into the chromium carbene bond in intermediate B affords vinyl carbene complex D, in which the C=C double bond may be either (Z) or (E). A putative chromacydobutene intermediate resulting from a [2+2] cydoaddition of the alkyne across the metal-carbene bond on the way to chromium vinylcarbene D, as was sometimes suggested in early mechanistic discussions, has been characterized as a high energy spedes on the basis of theoretical calculations [9c]. Its formation and ring-opening cannot compete with the direct insertion path of the alkyne into the chromium-carbene bond. An example of an (E)-D alkyne insertion product has been isolated as the decarbonylation product of a tetracarbonyl chromahexatriene (4, Scheme 4) [14], and has been characterized by NMR spectroscopy and X-ray analysis. 

The stepwise coupling of two cis ligands as depicted in Scheme 3 has been verified as involving a sequence of three discrete steps at low temperatures, allowing the isolation of the relevant intermediates as individual compounds [18]. When a chelated tetracarbonyl amino-vinyl carbene complex (chelated analogue of intermediate B in Scheme 3) was reacted with an electron-deficient alkyne under controlled conditions, a l,4,5- 3-dienylcarbene tetracarbonyl chromium complex (corresponding to intermediate D in Scheme 3) was formed. It underwent thermal decomposition to give phenol derivatives as the final products. 

The facile decarbonylation of pentacarbonyl complexes 23a and 23b results in tetra-carbonyl carbene complex intermediates 24a and 24b, respectively. Their annulation can produce benzene and/or cyclopentadiene derivatives 25 and/or 26. In the case of aryl acyla-mino complex 23a, the reaction course is shifted towards the benzannulation reaction (25a 26a = 84 16). With the vinyl carbene complex 23b, the benzannulation product 25b (25b 26b = 100 0) is produced exclusively. 

In contrast to aryl carbene complexes, vinyl carbene complexes are known to yield only the benzannulation products [37]. For instance, carbohydrates [38], tetramethyl ketals of qui-nones [39], heterocycles, and oxacycloalkenylidene carbene complexes [40] have been used as part of a (cyclic) vinyl carbene complex. For example, complex 29 and diphenylethyne were converted to the acyl hydroquinone 30. Thus, 29 serves as a synthon for the (electron-poor) benzoyl vinyl carbene complex (Scheme 14) [40]. 

Scheme 14. Complex 29 acting as an acyl vinyl carbene complex synthon in the benzannulation reaction.

The only example of a vinyl carbene complex bearing fluoro substituents that has been benzannulated is presented in Scheme 15 [41]. Carbene complex 31 was reacted with diphenylethyne to give hydroquinone 32. Interestingly, one of the fluoro substituents in the educt is lost in the reaction. 

Three different strategies have been envisaged. The chiral information can either be incorporated into the alkyne or linked to the heteroatom or to the a,/ -unsaturated substituent at the carbene complex carbene carbon. High diastereoselectivities (57a 57b >96 4) have been observed in reactions of vinyl carbene complex 55 with the chiral propargylic ether 56 bearing the bulky trityloxy substituent [57a]. A more general approach is based on chiral alcohols incorporated into the alkoxycarbene complex. Upon benzannulation with tert-butylethyne, the menthyloxy carbene complex 58 gave a diastereoselectivity of 10 1 in favor of the naphthalene tricarbonylchromium complex 59a [57c, 57d]. Finally, the tandem benzannulation-Mitsunobu reaction of optically active carbene complex 60 with 5-hexyn-l-ol afforded the anti-benzoxepine complex 61 as the only diastereomer (Scheme 23) [57b]. 

The mechanism proposed by Ddtz involves the insertion of a carbon monoxide into the vinyl carbene complex intermediate with the formation of the vinyl ketene complex (255). Electrocyclic ring closure of (255) leads to the cyclohexadienone complex (252), which is related to the final tenzannulation product by a tautomerizadon when R is hydrogen. The mechanism proposed by Casey differs from that of Ddtz in that the order of the steps involving carbon monoxide insertion and cyclization to the aryl or alkenyl substiment is reversed. < Specifically, the vinyl carbene complex intermediate (248) first undergoes cyclization to the metallacyclohexadiene (249), followed by cartion monoxide insertion to give the intermediate (251), and finally reductive elimination to give cyclohexadienone intermediate (252). At this time the circumstantial evidence favors the intermediacy of vinyl ketene intermediates since they can be trapped from these reactions and isolated where the metal is dispaced from the vinyl ketene functionality however, there is not any evidence which can rule out the alternative mechanism. 

The two-alkyne annuation reactions shown in Scheme 43 are actually reactions of this class since mechanistically they can be viewed as the interception of vinyl carbene complex intermediate (248) in Scheme 36 by an aU ne. In addition to alkynes, intermediates from the reactions of Fischer complexes... 

In a variation of the reactions in Scheme 44, Rudler has reported that the alkene which intercq)ts the vinyl carbene complex leading to cyclopropane products can be tethered onto the starting carbene complex.This was extensively studied for the reaction of the carbene complex (334) with a number of alkynes leading to bicycloheptanones of the type (336). ° This reaction is quite general (14 examples, 44-95%) and is regioselective with terminal alkynes, i.e. it occurs in the same sense that has been observed for the benzannuladon reaction (R = H in 336). Acetylene fails and cyclooctyne gives a reduced... 

Scheme 6.19 Alternative synthesis of vinyl carbene complexes.

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