Cyclic carbenes complex

Although most of the examples of [3S+2C] cycloaddition reactions with carbene complexes are referred to as 1,3-dipolar processes, we should include in this section another kind of non-dipolar transformation dealing with the reaction of pentacarbonyl(methoxymethylcarbene)chromium with a base followed by treatment with an epoxide in the presence of boron trifluoride. This reaction gives cyclic carbene complexes in a process that can be considered a [3S+2C] cycloaddition [44] (Scheme 14). 

J-Oxygen-functionalised sp3 organolithium compounds react with alkenyl-carbene complexes to generate the corresponding cyclic carbene complexes in a formal [3+3] process (see Sect. 2.8.1). In those cases where the organolithium derivative contains a double bond in an appropriate position, tricyclic ether derivatives are the only products isolated. These compounds derive from an intramolecular cyclopropanation of the corresponding cyclic carbene complex intermediate [89] (Scheme 83). 

The cyclic carbene complex shown in equation 3.4 was studied by X-ray diffraction [66], it shows a linear complex (angle C—Au—C 178.6(4)°) and the gold aryl bond distance is 1.993(10) A which is in accordance with such bonds in other known pentafluorophenyl complexes. The gold carbene carbon distance is 1.961(9) A, the dihedral angle between the planes formed by the two organic ligands is 5.35° and the shortest intermolecular Au—Au distance is 3.95 A. 

Os(II) complexes of tosylmethylisocyanide react with aldehydes and ketones in the presence of sodium methoxide, producing cyclic carbene complexes (66). Compound 32 undergoes a rapid reaction with benzal-dehyde and NaOMe, yielding the oxazol-2-ylidene complex 33 and eliminating p-toluene sulfinic acid (66) ... 

Obviously, the first intermediates in the syntheses with terminal alkynols are the vinylidene complexes [Ru(bdmpza)Cl(=C= CH(CH2) +iOH)(PPhg)] (n = 1, 2), which then react further via an intramolecular addition of the alcohol functionality to the a-carbon (Scheme 22), although in none of our experiments we were able to observe or isolate any intermediate vinylidene complexes. The subsequent intramolecular ring closure provides the cyclic carbene complexes with a five-membered ring in case of the reaction with but-3-yn-l-ol and with a six-membered ring in case of pent-4-yn-l-ol. For both products type A and type B isomers 35a-I/35a-II and 35b-I/ 35b-II are observed (Scheme 22, Fig. 22). The molecular structure shows a type A isomer 35b-I with the carbene ligand and the triphenylphosphine ligand in the two trans positions to the pyrazoles and was obtained from an X-ray structure determination (Fig. 25). 

In 1985, Dbtz et al. reported during a study on the reaction of Fischer-type carbene complexes with alkynes [10] that 2-oxacyclopentylidene chromium complex 24 was obtained as a side product. Thus, treatment ofmethyl(methoxy)carbene complex with 3-butynol at 70 °C in dibutyl ether gave the cyclic carbene complex 24 in 23% yield along with the desired metathesis product 23. The authors briefly commented that the cyclic carbene complex 24 might be obtained through the vinylidene complex 25, generated by the reaction of the alkyne with the liberated pentacarbonylchromium species (Scheme 5.7). 

Then, in 1987, Dotz reported an improved procedure for this transformation, for which the use of Et20 as solvent improved the yield of the cyclic carbene complexes considerably [12]. For example, the five-membered Fischer-type carbene complex 29 (n=l) was prepared in 58 66% yield by the reaction of preformed M(CO)5(L) (M = Cr, W, L = Et20) and 3-butynol in Et20 at room temperature. The six-membered cyclic carbene complex could also be prepared by this method. This method has been applied to the preparation of functionalized cyclic Fischer-type carbene complexes from the corresponding alkynols. For example, Dotz et al. reported the preparation of various carbohydrate-functionalized cyclic Fischer-type carbene complexes, one of which is shovm in Scheme 5.9. 

Schmidt et al. reported similar reactions of 3-butynols with Cr(CO)5(L) and Mo(CO)5(L) [18]. In most cases, a similar tendency to that reported by McDonald was observed, that is, five-membered cyclic carbene complexes were obtained when Cr(CO)5(OEt2) was employed, while dihydrofurans were obtained when Mo(CO)5 (NEt3) was employed, however, in one specific case, a unique difference of the reaction pathway was observed. Thus, when hemiacetal 44 was treated with Cr (CO)5(OEt2), the corresponding carbene complex 45 was obtained, which was further converted to dihydrofuran by treatment with DM AP. On the other hand, when 44 was... 

Cyclic Carhene Complexes. The reaction of aziridines with carbonyl, thiocarbonyl, or isonitrile ligands in Mn, Re, Fe, Ru, Pd, or Pt complexes leads to formation of cyclic carbene complexes (324—331). 

Rapid intramolecular addition of the alcohol function to a supposed intermediate vinylidene complex occurs in reactions of HC=C(CH2) OH with metal halide complexes (45) the cyclic carbene complexes (17) are isolated instead ... 

The conventional vinylidene complex could be isolated when the hydroxyl group was protected as the tetrahydropyranyl ether derivative reaction of this with acid immediately gave the cyclic carbene complex, even under mild conditions. The reaction is related to the formation of similar nickel(II)- and platinum(IV)-carbene complexes from the [Pg.71]

The reaction with 4-pentyn-l-ol gave only [Fe t/2-CH2=C(CH2)30) (CO)2(t/-C5H5)]+, and 3-hexyn-l-ol afforded (64, R = Et) (84) no evidence for the participation of the vinylidene tautomers was found. With ruthenium (45) and platinum (47) complexes, on the other hand, rearrangement to the vinylidene is faster than internal attack on the >/2-alkyne, and only the cyclic carbene complex is formed. 

Addition of the acetylenic alcohols HC=C(CH2) OH (x = 3,4) to 1 affords a one-pot synthesis of the cyclic carbene complexes (88). The reaction proceeds via initial formation of the vinylidene complexes, followed by an intramolecular attack of the terminal alcohol function on the a carbon [Eq. (84)] (85). Combining the nucleophilicity at the /3 carbon of... 

Complex 3c, a catalytic precursor for addition reactions to alkynes (65), reacts at room temperature with a variety of terminal alkynes in alcohols to produce stable alkoxyl alkyl carbene ruthenium(II) derivatives 109 in good yields (Scheme 7). Reaction of 3c (L = PMe3), with trimethylsilyacetylene in methanol gives the carbene ruthenium complex 110, by protonolysis of the C—Si bond, whereas with 4-hydroxy-l-butyne in methanol the cyclic carbene complex 111 is obtained (65,66). 

Complexes of type [LyM (CH2)IIX ], where n > 1, have been shown to be useful precursors for hetero- and homobimetallic n(a.,a>) alkanediyl complexes, [LjcM(CH2)bM L, ] (where ML, is not necessarily the same as M Lj,). Such hydrocarbon-bridged binuclear compounds have been proposed as models for intermediates in the Fischer-Tropsch reaction (18,19) and other significant catalytic processes (20-23). Some [LyM (CH2)BX ] complexes are precursors to cyclic carbene complexes (Section III), whereas others have been shown to have synthetic utility in organic chemistry (24). 

Ofele, Herberhold, and co-workers (169-172) have examined the photochemistry of a series of cyclic carbene complexes of Cr, Mo, and W, and their results appear consistent with CO dissociation. It was first noted... 

The sulfur ylid Me2S(0)CH2 is a very weak base, and, when coordinated to nickel in the complex [Ni( / -C2H4)2CH2S(0)Me2] (91), spontaneous decomposition to ethane, cyclopropane, and methane occurs (93). In another reaction, compound 92 rearranges under UV irradiation to yield, with insertion of iron into a phenyl-carbon bond, a cyclic carbene complex, 93 94). 

The cyclic carbene complex (23) formed in equation 10.722 is analogous to the original Fischer-type carbene complex. The ring, however, offers an added complexity that has utility in the realm of organic synthesis. 

SCHEME 33. Cyclic carbene complexes from bis(isocyanides)... 

This increase in acidity is mainly the result of the weaker 77-donor effect of the MeS (c7r = - 0.15) " compared to that of the MeO group (ctr = - 0.43) " which leads to a weaker stabilization of the neutral thia compared to the oxa carbene complexes. The higher pK values of entries 1-3 compared to that of 5 can be attributed to 77-donation by the respective oxygens in entries 1-3 that is stronger than in 5. In the case of entry 3, the ethyl group is a better stabilizer of the oxyanion resonance structure of the carbene complex (140). For the cyclic carbene complexes (entries 1 and 2), the 77-donor effect is enhanced further because, by virtue of the cyclic structures of entries 1 and 2, the oxygen is locked into a position for better 77-overlap with carbene carbon (142). Cr NMR data are in agreement with this assessment. ... 

The hydrolysis of 146 (isopropyl carbene) is also catalyzed by light although the effect is smaller than for 144a or 144b and the phenomenon was not studied in detail. On the other hand, no light-induced rate accelerations were observed for the hydrolysis of the cyclic carbene complexes 8 and 141, " or of the ethyl carbene complex 145. " It is unclear at this point what structural factors power the photochemical reaction shown in Scheme 18. 

The allenylidene complex 43 is stable in acetone solution. However, the addition of potassium hydroxide gives rise to the functionalized alkynyl derivative Ru(Ti5-C5H5) CsCC(Ph)2CH2C(0)CH3 (C0)(PiPr3) (50), which is a result of the selective attack of the enolate of the ketone to the atom of the allenylidene ligand of 43. Complex 50 reacts with HBF4-OEt2 to afford the unsaturated cyclic carbene complex 51 in 86% yield (Scheme 15) [23]. 

From a methodological point of view, it should be pointed out the formation of 51, which is a result of the addition of acetone to an allenylidene ligand. Heteroatom-containing cyclic metal-carbene complexes [24] have been conveniently prepared via metal co-haloacyl, carbamoyl, alkoxycarbonyl, or imido intermediates [25], opening of epoxides by deprotonated Fischer-type carbene complexes [26], and activation of homopropargylic alcohols with low-valent d complexes [27], including ruthenium(II) derivatives [28]. In general, the preparation of unsaturated cyclic carbene complexes requires the previous preparation of functional carbenes to react with P-dicarbonyl derivatives, acrylates, and enol ethers [29]. 

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