Rhodium azides

Scheme 1. Reactions between CF3C=CCF3 and some rhodium azides. 

The first rhodium tetrazolate complex Rh(5-CF3-tta)(PPh3)3 was obtained in 1969 by treatment of RhCl(PPh3)3 with Na(5-CF3-tta) (18). The complex Rh2( -5-CF3-tta)(/i-N3)(5-CF3tta)2(C5Mes)2, obtained by addition of CF3CN to the rhodium azide Rh2(/i-N3)2(N3)2(C5Me5)2,... 

Intermediate 37 can be transformed into ( )-thienamycin [( )-1)] through a sequence of reactions nearly identical to that presented in Scheme 3 (see 22— 1). Thus, exposure of /(-keto ester 37 to tosyl azide and triethylamine results in the facile formation of pure, crystalline diazo keto ester 4 in 65 % yield from 36 (see Scheme 5). Rhodium(n) acetate catalyzed decomposition of 4, followed by intramolecular insertion of the resultant carbene 3 into the proximal N-H bond, affords [3.2.0] bicyclic keto ester 2. Without purification, 2 is converted into enol phosphate 42 and thence into vinyl sulfide 23 (76% yield from 4).18 Finally, catalytic hydrogenation of 23 proceeds smoothly (90%) to afford ( )-thienamycin... 

The NHCs have been used as ligands of different metal catalysts (i.e. copper, nickel, gold, cobalt, palladium, rhodium) in a wide range of cycloaddition reactions such as [4-1-2] (see Section 5.6), [3h-2], [2h-2h-2] and others. These NHC-metal catalysts have allowed reactions to occur at lower temperature and pressure. Furthermore, some NHC-TM catalysts even promote previously unknown reactions. One of the most popular reactions to generate 1,2,3-triazoles is the 1,3-dipolar Huisgen cycloaddition (reaction between azides and alkynes) [8]. Lately, this [3h-2] cycloaddition reaction has been aided by different [Cu(NHC)JX complexes [9]. The reactions between electron-rich, electron-poor and/or hindered alkynes 16 and azides 17 in the presence of low NHC-copper 18-20 loadings (in some cases even ppm amounts were used) afforded the 1,2,3-triazoles 21 regioselectively (Scheme 5.5 Table 5.2). 

The sulfamate ester variant of this chemistry has already been shown to be a very powerful protocol for the syntheses of 1,3-amino alcohols and related /3-amino acids (Equation (90)), as well as iminium ion equivalents (Equation (91)). The further showcases of this chemistry are the total syntheses of the bromopyrrole alkaloids, manzacidins A and C (Scheme 13).234 The cyclic sulfamidate 129 was obtained diastereospecifically from sulfamate 128 using intramolecular rhodium-catalyzed G-H insertion. It was then found to react with sodium azide in NfN-dimethylformamide at room temperature after introduction of the Boc-activating group to afford the 1,3-diamino precursor 130 in 78% yield over 3 steps. Four subsequent manipulations afford the target structure 131. 

A series of 12 complexes of Co(III) with both ionic and covalent azide groups was prepared and most were easily detonable as dry salts, especially at elevated temperatures [1]. Polarography is an accurate and safe method of analysis for azides [2], Hexaammine-cobalt, -chromium and -rhodium hexaazidocobaltates are explosive, particularly in the dry state [3],... 

Many nucleophiles act as inhibitors of platinum, palladium and rhodium catalysts. The strongest are mercaptans, sulfides, cyanide and iodide weaker are ammonia, azides, acetates and alkalis [26]. 

Analysis of the reaction KIE using monodeuterated sulfamate 106 reinforces the proposed rhodium-nitrene model (Eq. 9). The ratio of H/D products 107/108 is a direct measure of the KIE and has been found to equal 1.5 0.2 by integration of the C NMR spectrum. An equivalent value is obtained for nitrene C-H insertion upon photolysis of a carbamoyl azide, and is taken as evidence for a nonlinear transition state. As noted previously, Muller s use of NsN=lPh with partially deuterated adamantane gives... 

One of the key steps in building the fused ring involves the reaction of the activated acetoacetate methylene group in that compound with toluenesulfonyl azide to give the diazo intemediate (12-1). Treatment of that product with rhodium acetate leads to a loss of nitrogen with the consequent formation of carbene (12-2) this inserts into the adjacent amide N—H bond to form a five-membered ring and thus the carbapenem (12-3) [15]. The first step in the incorporation of the thioenol function consists in the conversion of the ketone to the enol phosphate derivative... 

Reaction of pyrido[2,l-6][l,3]thiazine-2,4-dione (105) with p-tosyl azide in the presence of triethylamine in acetonitrile at 0°C gave a 3-diazo derivative (106), which reacted with cyclohexene in the presence of a catalytic amount of rhodium acetate under reflux to yield a spiro derivative (107) [94H(39)219 95H(41)1631]. 

The synthesis of the iridium(III) azide complex (Bu N)3[Ir(N3)6] occurs via reaction (75). The visible and near-UV absorption and reflection spectra of this complex have been recorded the assignment of bands in this and rhodium(III) azide complexes has led to the location of the Nf ligand in the spectrochemical and nephelauxetic series.283... 

From Figure 3.15 it is clear that the bulky, ortho-Mes substituted, pyridine donor cannot displace an anionic ligand (chloride, azide) from the coordination sphere of the rhodium(I) centre. Likewise, the bulky pyridine donor is displaced by triphenyl phosphane, whereas the... 

The synthetic potential of reductions by formate has been extended considerably by the use of ammonium formate with transition metal catalysts like palladium and rhodium. This forms a safe alternative to use of hydrogen. In this fashion it is possible to reduce hydrazones to hydrazines, azides and nitro groups to amines, to dehalogenate chloro-substituted aromatics, and to carry out various reductive removals of functional groups. For example, phenol triflates are selectively deoxygenated to the aromatic derivatives using triethylammonium formate as reductant and a palladium catalyst. - These recent af li-cations have been reviewed. 

An enantiomerically pure aldehyde, (lR,2R,3R)-2,7,7-trimethylbicyclo[3.1.1]hep-tane-2-aldehyde, is produced from a-pinene by rhodium-catalyzed hydroformylation [79, 80]. Initially, reaction with ferrocene under acidic conditions leads to a 1 1 mixture of diastereoisomeric cations, but on standing for a few hours at room temperature, isomerization by rotation around the ferrocene — cationic carbon bond to the thermodynamically more stable cation (with configuration (R) at the cationic center) occurs (Fig. 4-11). An enantiomerically pure amine is available by trapping of this cation by azide and reduction [75]. Analogously, the isomeric aldehyde with the bicyclo [2.2.1] heptane structure is formed by hydroformylation of a-pinene with cobalt catalysts [79, 80] and was used as the starting material for an isomeric series of chiral amines [75]. 

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