Carbene insertion reactions copper

The initial question was whether the active catalyst is copper metal, copper(I), or copper(II), because all metal precursors gave results. Without the proper control of the valence state and the ligand environment the selectivities for the copper catalysed cyclopropanations (or carbene insertion reactions) have remained low or inconsistent for a long period of time. It was only in the sixties that a more systematic study of these issues was started. Several divalent copper salts were successfully used, but Kochi and Salomon [1] showed with the use of Cu(I)OTf that most likely copper(I) was the actual species needed for this reaction. 

Formally, the insertion of a carbene(oid) into the 2,3-doubIe bond of the thiophene ring should result in the formation of the 2-thiabicyclo [3.1.0] hex-3-ene ring system. Copper(II)-catalyzed reaction of thiophene with diazomethane results in the formation of 24 (R = H) in modest yield (63TL1047). Analogously, the reaction of thiophene with ethyl diazoacetate yields 24 (R = COjEt) (22LA154). Although these reactions appear to be simple carbene insertion reactions, it is probable that this simple mechanism is not in operation. Rather, the cyclopropane derivatives 24 probably result from the initial formation of the ylid (e.g., 18), which subsequently rearranges. 

This carbene insertion reaction has been used in a variety of syntheses, and is especially attractive when coupled with other synthetic techniques. Taber et al. used carbene cyclopropanation in several synthetic endeavors. In one example, the diazoketone was treated with bis-A-tert-butylsalicylaldiminato copper(II) [Cu(TBS)2, 388] to induce the carbene cyclopropanation reaction. The diazoketone was prepared by treating 386 with mesyl azide to give 387 in 82% yield, which was followed by treatment with the Cu(TBS)2 reagent to produce 389 in 80% yield in Taber and co-workers synthesis of (-i-)-isoneonepatelactone.308... 

Photolytically generated carbene, as mentioned above, undergoes a variety of undiscriminated addition and insertion reactions and is therefore of limited synthetic utility. The discovery (3) of the generation of carbenes by the zinc-copper couple, however, makes carbene addition to double bonds synthetically useful. The iodo-methylzinc iodide complex is believed to function by electrophilic addition to the double bond in a three-center transition state giving essentially cis addition. Use of the... 

The view has been expressed that a primarily formed ylide may be responsible for both the insertion and the cyclopropanation products 230 246,249). In fact, ylide 263 rearranges intramolecularly to the 2-thienylmalonate at the temperature applied for the Cul P(OEt)3 catalyzed reaction between thiophene and the diazomalonic ester 250) this readily accounts for the different outcome of the latter reaction and the Rh2(OAc)4-catalyzed reaction at room temperature. Alternatively, it was found that 2,5-dichlorothiophenium bis(methoxycarbonyl)methanide, in the presence of copper or rhodium catalysts, undergoes typical carben(oid) reactions intermole-cularly 251,252) whether this has any bearing on the formation of 262 or 265, is not known, however. 

Electrophilic carbene complexes generated from diazoalkanes and rhodium or copper salts can undergo 0-H insertion reactions and S-alkylations. These highly electrophilic carbene complexes can, moreover, also undergo intramolecular rearrangements. These reactions are characteristic of acceptor-substituted carbene complexes and will be treated in Section 4.2. 

The first reports of N-H insertion reactions of electrophilic carbene complexes date back to 1952 [497], when it was found that aniline can be N-alkylated by diazoacetophenone upon treatment of both reactants with copper. A further early report is the attempt of Nicoud and Kagan [1178] to prepare enantiomerically pure a-amino acids by copper(I) cyanide-catalyzed decomposition of a-diazoesters in the presence of chiral benzylamines. Low enantiomeric excesses (< 26% ee) were obtained, however. 

Working with diazo compounds, known since the early 1900s to undergo loss of dinitrogen when treated with copper or copper salts, Yates described in 1952 the possibility that transition metals could form an intermediate that combined units of the diazo compound and the metal (Eq. 1, L = ligand) and acted like a carbene in addition and insertion reactions. Somewhat later, but independently, E. O. Fischer isolated and characterized stable metal carbenes that could also undergo cyclopro-panation reactions." They were derived from transition metals on the left side of the... 

Catalytic methods are suitable for nitrene transfer," and many of those found to be effective for carbene transfer are also effective for these reactions. However, 5- to 10-times more catalyst is commonly required to take these reactions to completion, and catalysts that are sluggish in metal carbene reactions are unreactive in nitrene transfer reactions. An exception is the copper(ll) complex of a 1,4,7-triaza-cyclononane for which aziridination of styrene occurred in high yield, even with 0.5 mol% of catalyst. Both addition and insertion reactions have been developed. 

Photochemical or copper-catalyzed decomposition of diazo compound 85 failed to give a handle on 2-silanaphthalene 87 (equation 19)49,50. Instead of the expected 1,2-Ph migration, carbene 86 apparently underwent simply an 0,H insertion reaction with methanol in 96% yield. 

In another copper-mediated carbene transfer reaction, diazoester 222 has been decomposed in the presence of bis(triethylsilyl- or -germyl)mercury (equation 72) it was assumed that the obtained ketenes 223 result from the insertion of ethoxycarbonyl(trimethylsilyl)carbene into a Hg-element bond followed by a cyclic fragmentation process110. 

In addition to the preparations of ethanoadamantane via Lewis acid catalyzed rearrangement of various polycyclic hydrocarbons described above (Section II. A.1), a ring closure reaction of a substituted adamantane has also been developed. Treatment of 2-adamantyl diazoketone with copper results in the intramolecular carbene insertion illustrated in Eq. (48) 14°1. 

Dichlorocarbene is a typical singlet ground-state carbene which is commonly used for cydopropanation reactions, since it gives satisfactory yields in many cases, but in general, carbene synthesis implies a metal catalyst (usually copper) together with a diazo compound as the carbene precursor. In (he particular case of the O -H insertion reaction, sulfur dioxide has been reported as being an efficient catalyst for the insertion of carbalkoxycarbenes generated from diazoesters. 

Metal Carbene TVansformations. The effectiveness of Rh2(55 -MEPY)4 and its 5R-form, Rh2 5R-MEPY)4, is exceptional for highly enantioselective intramolecular cyclopropanation and carbon-hydrogen insertion reactions. Intermolecular cyclopropanation occurs with lower enantiomeric excesses than with alternative chiral copper salicylaldimine or C2-symmetric semicorrin or bis-oxazoline copper catalysts, but intermolecular cyclopropenation exhibits higher enantio-control with Rh2(MEPY)4 catalysts. The methyl carboxylate attachment of Rh2(55-MEPY)4 is far more effective than steri-cally similar benzyl or isopropyl attachments for enantioselective metal carbene transformations. The significant enhancement in enantiocontrol is believed to be due to carboxylate carbonyl stabilization of the intermediate metal carbene and/or to dipolar influences on substrate approach to the carbene center. 

As already mentioned for rhodium carbene complexes, proof of the existence of electrophilic metal carbenoids relies on indirect evidence, and insight into the nature of intermediates is obtained mostly through reactivity-selectivity relationships and/or comparison with stable Fischer-type metal carbene complexes. A particularly puzzling point is the relevance of metallacyclobutanes as intermediates in cyclopropane formation. The subject is still a matter of debate in the literature. Even if some metallacyclobutanes have been shown to yield cyclopropanes by reductive elimination [15], the intermediacy of metallacyclobutanes in carbene transfer reactions is in most cases borne out neither by direct observation nor by clear-cut mechanistic studies and such a reaction pathway is probably not a general one. Formation of a metallacyclobu-tane requires coordination both of the olefin and of the carbene to the metal center. In many cases, all available evidence points to direct reaction of the metal carbenes with alkenes without prior olefin coordination. Further, it has been proposed that, at least in the context of rhodium carbenoid insertions into C-H bonds, partial release of free carbenes from metal carbene complexes occurs [16]. Of course this does not exclude the possibility that metallacyclobutanes play a pivotal role in some catalyst systems, especially in copper-and palladium-catalyzed reactions. 

Addition of carbenes to aromatic systems leads to ring-expanded products. Methylene itself, formed by photolysis of diazomethane, adds to benzene to form cycloheptatriene in 32% yield a small amount of toluene is also formed by an insertion reaction. The cycloheptatriene is formed by a Cope rearrangement of the intermediate cyclopropane (a norcaradiene). More satisfactory is the reaction of benzene with diazomethane in the presence of copper salts, such as copper(I) chloride, which gives cycloheptatriene in 85% yield (4.87). The reaction is general for aromatic systems, substituted benzenes giving mixtures of the corresponding substituted cycloheptatrienes. 

The use of ylides as carbene precursors constitutes a novel original approach to control or extend carbenic reactions. The thiophenium ylide XXVIII prepared by catalytic decomposition of methyl diazomalonate in the presence of dichloro-2,5-thiophene has been successfully applied as a carbene equivalent or precursor to the cyclopropanation of olefins, the OH insertion and the C-H insertion reaction in activated arenes [112, 113] the catalyst being rhodium(II) acetate or copper(II) acetylaceto-nate. 

Diazo compounds, with or without metal catalysis, are well-known sources of carbenes. For synthetic purposes a metal catalyst is used. The diazo compounds employed are usually a- to an electron-withdrawing group, such as an ester or a ketone, for stability. In the early days, copper powder was the catalyst of choice, but now salts of rhodium are favoured. The chemistry that results looks very like the chemistry of free carbenes, involving cyclopropanation of alkenes, cyclopropenation of alkynes, C-H insertion reactions and nucleophilic trapping. As with other reactions in this chapter, free carbenes are not involved. Rhodium-carbene complexes are responsible for the chemistry. This has enormous consequences for the synthetic applications of the carbenes - not only does the metal tame the ferocity of the carbene, but it also allows control of the chemo-, regio- and stereoselectivity of the reaction by the choice of ligands. 

Lactams, and /S-lactams in particular, are interesting owing to their occurrence in biologically active compounds such as antibiotics related to penicillines. Insertion reactions of carbenes offer useful access to poly heterocyclic systems contain a -lactam nucleus, particularly when using rhodium and copper catalysis. Moreover, palladium catalyzed carbonyla-tion of azirines affords )S-lactam derivatives [93] in one step. 

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