Reactions with diazo compounds

The use of dirhodium(II) catalysts for catalytic reactions with diazo compounds was initiated by Ph. Teyssie [14] in the 1970s and rapidly spread to other laboratories [1]. The first uses were with dirhodium(II) tetraacetate and the more soluble tetraoctanoate, Rh2(oct)4 [15]. Rhodium acetate, revealed to have the paddle wheel structure and exist with a Rh-Rh single bond [16], was conve-... 

Scheme 6.1 Catalytic cycle of metal-catalysed carbenoid cyclopropanation reactions with diazo compounds.

Oxidation of phosphites to phosphazenes can also be achieved by reactions with diazo-compounds 38... 

Compounds with a Si=Si or Ge=Ge bond (i.e., disilenes and digermenes) can be isolated when the double bond contains bulky substituents. Only a few cycloaddition reactions with diazo compounds are known, and two reaction modes have been observed. One of the paths leads to the formation of disiliranes 184 (242) and digermiranes 185 (243) (Scheme 8.42), probably by ring contraction of an initially formed [3 + 2] cycloaddition product. The other path involves a 1,1-cycloaddition of the diazoalkane to give disilaaziridine 186 (244) and digermaazir-idine 187 (245). This nitrene-like reactivity is rather uncommon although some intramolecular examples are known (see Section 8.6.1). 

The generation and addition of acyl- and alkoxycarbonylcarbenes to alkenes is usually carried out by using the corresponding diazo derivatives under catalysis of metallic compounds. The metal-catalyzed cyclopropanation reactions with diazo compounds are described in detail by McKervey in Chapter 11, hence dealt with rather briefly in this chapter. The readers who are interested in the preparation of acyl- and alkoxycarbonyl-substi-tuted cyclopropanes are requested to refer also to Chapter 9. 

Rh(II) carboxylates, especially Rh2(OAc)4> have emerged as the most generally effective catalysts for metal carbene transformations [7-10] and thus interest continues in the design and development of dirhodium(II) complexes that possess chiral51igands. They are structurally well-defined, with D2h symmetry [51] and axial coordination sites at which carbene formation occurs in reactions with diazo compounds. With chiral dirhodium(II) carboxylates the asymmetric center is located relatively far from the carbene center in the metal carbene intermediate. The first of these to be reported with applications to cyclopropanation reactions was developed by Brunner [52], who prepared 13 chiral dirhodium(II) tetrakis(car-boxylate) derivatives (16) from enantiomerically pure carboxylic acids RlR2R3CC OOH with substituents that were varied from H, Me, and Ph to OH, NHAc, and CF3. However, reactions performed between ethyl diazoacetate and styrene yielded cyclopropane products whose enantiopurities were less than 12% ee, a situation analogous to that encountered by Nozaki [2] in the first applications of chiral Schiff base-Cu(II) catalysts. 

The molecular geometries and the frontier orbital energies of heterophospholes 28-31 were obtained from density functional theory (DFT) calculations at the B3LYP/6-311- -G, level. The 1,3-dipolar cycloaddition reactivity of these heterophospholes in reactions with diazo compounds was evaluated from frontier molecular orbital (FMO) theory. Among the different types of heterophospholes considered, the 2-acyl-l,2,3-diazaphosphole 28, 377-1,2,3,4-triazaphosphole 30, and 1,3,4-thiazaphosphole 31 were predicted to have the highest dipolarophilic reactivities. These conclusions are in qualitative agreement with available experimental results <2003JP0504>. 

Coupling reactions with diazo compounds which are very sensitive to alkali often are most successful when pyridine is used as an acidfixing agent. This is especially true in the preparation of secondary polyazo dyes with l-amino-2-naphthol ethers or their sulfonic acids as intermediates. ... 

In the coupling reaction with diazo compounds, the H is replaced by the —N=N—R groups. 

The following types of compounds undergo coupling reactions with diazo compounds (a) Phenols, (b) Enolizable keto compounds of an aliphatic character, having a reactive methylene group which may be part of an open chain or a ring system, either homocyclic or heterocyclic. This group of compounds may be represented by the formula ... 

Due to the electrophilic character of carbenes. they are not expected to easily react with electron-poor alkenes, and the only reported examples concern reactions with diazo compounds (i.e., diazomethane, diazofluorcnc. ethyl diazoacetate. and phenyldiazoniethane ). However, depending on the reaction conditions, carbenes arc not always the reactive species. Cyclopropanes are often obtained by decomposition of pyrazolines which arise from 1,3-dipolar cycloaddilion reactions (see Section 2.1.1.6.2.3.1.). Even when reactions are performed under irradiation, pyrazolines can be obtained as the result of a diradical addition. ... 

Finally, a racemic cyclopropanation process has also been developed that utilizes an iron Lewis acid catalyst (72) that presumably proceeds through an iron carbene intermediate (73) (Scheme 28). The catalyst is activated by reaction with diazo compounds to produce an intermediate (74) that loses dinitrogen see Dinitrogen Dinitrogen Complexes) to afford the cyclopropane. This chemistry has been extended to the production of epoxides and aziridines and has recently been reviewed. ... 

CiMLcoGEN Metal Complexes Used in Reactions with Diazo Compounds... 

Reaction with diazo compounds. Trilyl perchlorate Is a very efficient catalyst for the decomposition of diphenyidiazomethane with dimerization to tetraphenyl-ethylene. The reagent reacts with ethyl diazoacetate in acetonitrile to give ethyl... 

ISODURENE (527-53-7) CioH, Combustible liquid. Forms explosive mixture in air (flash point 160°F/71°C Fire Rating 2). Contact with strong oxidizers may cause fire and explosion. Violent reaction with diazo compounds. On small fires, use dry chemical powder (such as Piuple-K-Powder), alcohol resistant foam. 

The cycloaddition behavior of phosphaalkynes toward 1,3-dipoles is particularly pronounced. Thus, reactions with diazo compounds give rise to the 37/-l,2,4-diazaphospholes 12 or their l//-isomers, respectively [16,18]. Azides [18a, 19], nitrilium betaines [18a, 20] mesoionic species [21], and sextet dipoles such as selenoxocarbenes [22] react analogously to form heteroatom-substituted phospholes. 

Cyoloaddition Reactions. Examples of cycloaddition reactions of cyclopropenones are provided by reactions with diazo-compounds and aminodiene . 

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