Alkynes rhodium-catalyzed

Subsequently, cationic rhodium catalysts are also found to be effective for the regio- and stereoselective hydrosilation of alkynes in aqueous media. Recently, Oshima et al. reported a rhodium-catalyzed hydrosilylation of alkynes in an aqueous micellar system. A combination of [RhCl(nbd)]2 and bis-(diphenylphosphi no)propanc (dppp) were shown to be effective for the ( >selective hydrosilation in the presence of sodium dodecylsulfate (SDS), an anionic surfactant, in water.86 An anionic surfactant is essential for this ( )-selective hydrosilation, possibly because anionic micelles are helpful for the formation of a cationic rhodium species via dissociation of the Rh-Cl bond. For example, Triton X-100, a neutral surfactant, gave nonstereoselective hydrosilation whereas methyltrioctylammonium chloride, a cationic surfactant, resulted in none of the hydrosilation products. It was also found that the selectivity can be switched from E to Z in the presence of sodium iodide (Eq. 4.47). 

In addition, Wu and Li recently have developed an efficient rhodium-catalyzed cascade hydrostannation/conjugate addition of terminal alkynes and unsaturated carbonyl compounds in water stereoselectively (Scheme 4.5).88... 

Oshima et al. explored a cationic rhodium-catalyzed intramolecular [4+2] annulation of l,3-dien-8-ynes in water in the presence of sodium dodecyl sulfate (SDS), an anionic surfactant.132 When the substrate l,3-dien-8-yne was a terminal alkyne, the reaction provided an inter-molecular [2+2+2] product (Eq. 4.68). In water, a reactive cationic rhodium species was formed by the dissociation of the Rh-Cl bond in the presence of SDS. The SDS forms negatively charged micelles, which would concentrate the cationic rhodium species (Scheme 4.15). 

In a similar way as described for the hydroformylation, the rhodium-catalyzed silaformylation can also be used in a domino process. The elementary step is the formation of an alkenyl-rhodium species by insertion of an alkyne into a Rh-Si bond (silylrhodation), which provides the trigger for a carbocyclization, followed by an insertion of CO. Thus, when Matsuda and coworkers [216] treated a solution of the 1,6-enyne 6/2-87 in benzene with the dimethylphenylsilane under CO pressure (36 kg cm"2) in the presence of catalytic amounts of Rh4(CO)12, the cyclopentane derivative 6/2-88 was obtained in 85 % yield. The procedure is not restricted to the formation of carbocycles rather, heterocycles can also be synthesized using 1,6-enynes as 6/2-89 and 6/2-90 with a heteroatom in the tether (Scheme 6/2.19). Interestingly, 6/2-91 did not lead to the domino product neither could 1,7-enynes be used as substrates, while the Thorpe-Ingold effect (geminal substitution) seems important in achieving good yields. 

The rhodium-catalyzed intermolecular hydrative dimerization of 1-alkynes leads to a,/3-unsaturated ketones (Equation (190)).154... 

Similarly, ketimines (benzylimines of aromatic ketones) undergo the rhodium-catalyzed ortho-alkenylation with alkynes to give or/ o-alkenylated aromatic ketones after hydrolysis.61 This method is applied to an efficient one-pot synthesis of isoquinoline derivatives by using aromatic ketones, benzylamine, and alkynes under Rh catalysis (Equation (55)). 

The rhodium-catalyzed cyclization/hydrosilylation of internal diyne proceeds efficiently with high stereoselectivity (Scheme 106). However, terminal diynes show low reactivity to rhodium cationic complexes. Tolerance of functionalities seems to be equivalent between the rhodium and platinum catalysts. The bulkiness of the hydrosilane used is very important for the regioselectivity of the rhodium-catalyzed cyclization/hydrosilylation. For example, less-hindered dimethylethylsilane gives disilylated diene without cyclization (resulting in the double hydrosilylation of the two alkynes), and /-butyldimethylsilane leads to the formation of cyclotrimerization compound. 

Rhodium complexes catalyze hydrosilylation-cyclization of 1,6-allenynes in the presence of (MeO SiH.77 To avoid complex product distributions, the use of substrates possessing fully substituted alkyne and allene termini is imperative. As shown in the cyclization of 1,6-allenyne 62a, the regiochemistry of silane incorporation differs from that observed in the rhodium-catalyzed hydrosilylation-cyclization of 1,6-enynes (see Section 10.10.2.3.2). For allenyne substrates, allene silylation occurs in preference to alkyne silylation (Scheme 40). 

Addition of diphenyl disulfide (PhS)2 to terminal alkynes is catalyzed by palladium complexes to give l,2-bis(phe-nylthio)alkenes (Table 3)168-172 The reaction is stereoselective, affording the (Z)-adducts as the major isomer. A rhodium(i) catalyst system works well for less reactive aliphatic disulfides.173 Bis(triisopropylsilyl) disulfide adds to alkynes to give (Z)-l,2-bis(silylsulfanyl)alkenes, which allows further transformations of the silyl group to occur with various electrophiles.174,175 Diphenyl diselenide also undergoes the 1,2-addition to terminal alkynes in the presence of palladium catalysts.176... 

Introduction of two different chalcogen elements to the C-C unsaturated bond is of particular interest from both synthetic and mechanistic viewpoints. Therefore, extensive studies have been carried out on the development of the (RE)2/(R E )2 binary system without using RE-E R compounds, which are difficult to prepare. (Z)-l-Seleno-2-thio-1-alkenes are produced regio- and stereoselectively when a mixture of diaryl disulfides and diaryl diselenides is subjected to a rhodium-catalyzed reaction with alkynes (Equation (68)).193... 

It took another decade however before the idea of developing a rhodium-catalyzed olefin hydroboration process came to fruition. This occurred in 1985 when Mannig and Noth reported the first examples of such a process.8 They discovered that Wilkinson s catalyst 2 was effective for the addition of catecholborane 1 to a range of alkenes and alkynes, as exemplified by cyclopentene 4 (Scheme 2). 

The rhodium-catalyzed enantioselective hydrogenation of enol esters is an alternative to the asymmetric reduction of ketones. Although enol esters are accessible both from ketones and alkynes, the number of studies reporting successful asymmettic hydrogenation has been limited. It appears that, compared... 

Scheme 4.S8. Zirconium- and rhodium-catalyzed hydroborations of alkenes and alkynes with pinacolborane.

Table 10 Rhodium-catalyzed hydrophosphinylation of alkynes with Ph2P(0)H...

Rhodium( )-Catalyzed Asymmetric Hydroacylation of Olefins and Alkynes with Aldehydes I 85... 

The most significant progress that has been described to date in the area of rhodium-catalyzed asymmetric hydroacylation of olefms/alkynes with aldehydes has involved intramolecular processes that generate either cyclopentanones or cyclopentenones. Fig. 4.2 illustrates two of the more likely mechanisms for these ring-forming reactions [12, 13]. 

For preliminary mechanistic studies of the rhodium-catalyzed cyclization of 4-alkynals... 

A moderate pressure (>5 atm.) of CO in the reaction system leads to the selective formation of 29, while alkynes undergo rhodium-catalyzed hydrosilylation with a hydrosilane to afford vinylsilanes in the absence of CO. The presence of the rhodium complex is crucial for the smooth progression of siiyiformyiation, regardless of the presence of mononuclear or polynuclear complexes. This generalization is supported by the studies of many others [15]. The most important feature of this reaction is the excellent regioselectivity, which favors the formylation of the internal sp-carbon of the acetylenic bond of terminal... 

An interesting appHcation of the rhodium-catalyzed cyclotrimerization of diynes with alkynes to the synthesis of C-acyl glycosides has been reported, wherein ethynylglycal 52 (Eq. 15), as well as diethynylglucose derivative 54 (Eq. 16), are employed to give the corresponding adducts 53 and 55, respectively [38]. 

Rhodium-catalyzed alkyne cyclotrimerization is also applicable to the synthesis of a polyalkyne substrate bearing ether-linked 1,6-diyne moieties 59, which is easily prepared by Pd-Cu-catalyzed Sonogashira couphng reactions. These reactions provide a novel and efficient synthetic route to oligophenylene 60, which bears benzodihydrofur-an moieties (Scheme 7.17) [40]. 

Zhang has proposed a mechanism for the rhodium-catalyzed Alder-ene reaction based on rhodium-catalyzed [4-1-2], [5-i-2], and Pauson-Khand reactions, which invoke the initial formation of a metallacyclopentene as the key intermediate (Scheme 8.1) [21]. Initially, the rhodium(I) species coordinates to the alkyne and olefin moieties forming intermediate I. This intermediate then undergoes an oxidative cycHzation forming the metallacyclopentene II, followed by a y9-hydride elimination to give the appending olefin shown in intermediate III. Finally, intermediate III undergoes reductive elimination to afford the 1,4-diene IV. 

The trienes were then subjected to a formal Diels-Alder reaction using conditions developed by Gilbertson and others (Scheme 8.7) [34]. The propargyl tosylamide 40 and the propargyl ether 43 have both afforded the formal intramolecular Diels-Alder adducts 44 and 45 in high yield. To date, the formal cycloaddition of the siHcon-teth-ered alkyne 41 has not been affected and heating triene 42 led to a thermal Diels-Alder reaction to furnish cycloadduct 46, albeit in lower yield than the corresponding rhodium-catalyzed examples. 

Since the PK reaction with electron-defident alkynes was also problematic, even when stoichiometric Co2(CO)g was employed, promoters such as trialkylamine N-oxide were required for the reaction to proceed [14]. Alternatively, W(CO)5-THF may be employed semi-catalytically for this class of substrates [9cj. The rhodium catalyst [RhCl(CO)2]2, has shown great versatility for electron-deficient alkynes (Scheme 11.4) the reaction times are much shorter (1-3 h) than those of the usual examples (Tab. 11.3). This rhodium-catalyzed PK reaction may be extended to the synthesis of 6,5-fused ring analogs, as exemplified in the synthesis of bicyclo[4.3.0]nonenone 2o from the 1,7-enyne lo (Eq.4) [13 bj. 

The rhodium-entrapped cage compound which is formed using a stoichiometric amount of [RhCl(CO)2]2 is a notable paradigm of the rhodium-catalyzed [2-I-2-I-1] al-kyne-alkyne and CO coupling [35]. Heating 57 in acetone at 50 °C for 8 h or irradiation by a tungsten or mercury lamp provided the cage compound in 50% yield based on NMR spectroscopy. However, due to mechanical losses it was isolated in only 16% yield from the reaction mixture, by crystallization as the hexafluorophosphate salt 58 (Eq. 13). 

Witulski and Alayrac reported the synthesis of clausine C (clauszoline-L) (101) by a rhodium-catalyzed alkyne cyclotrimerization of diyne 1014 and propiolic ester 635 (561). Analogous to the hyellazole (245) synthesis (see Scheme 5.75), the diyne precursor 1014 required for this key cyclotrimerization reaction was obtained starting from readily available 2-iodo-5-methoxyaniline. Using Wilkinson s catalyst, [RhClfPPhsls], crossed-alkyne cyclotrimerization of 1014 and 635 led to N-tosylclausine C (1015) in 78% yield in an isomeric ratio of 3.8 1. Finally, deprotection of the tosyl group with TBAF in refluxing TFIF afforded clausine C (clauszoline-L) (101) (561) (Scheme 5.147). 

The addition of Rh-Csp a-bonds to enones is a well-studied process. Lee s reaction is predicated on the idea that rhodium-catalyzed conjugate addition of boronic acids to enones can be interrupted by 1,1-insertion into an alkyne. Thanks to the high reactivity of rhodium toward alkynes and the effects of tethering, a partly intramo-... 

Doyle et al. (39) expanded the rhodium-catalyzed generation of isomiinchnones from diazoacetacetamides and subsequent trapping with dipolarophiles (38). As shown in Scheme 10.12, in the case of diazoacetoacetyl urea (79) the derived isomtinchnone 80 reacts with methyl propiolate to give a 2 1 mixture of cycloadducts 81. The resulting regiochemistry is successfully rationalized using frontier molecular orbital (FMO) theory as being isomiinchnone-HOMO controlled. This result represents one of the few reactions in which the cycloadducts from isomiinchnones and alkynes are stable. 

Gowravaram and Gallop (169) adapted the rhodium-catalyzed generation of isomiinchnones from diazo imides to the solid-phase synthesis of furans, following a 1,3-dipolar cycloaddition reaction with alkynes. A variety of furans were prepared in this fashion. With unsymmetrical electron-deficient alkynes (e.g., methyl... 

Gyclization/hydrosilylation of enynes catalyzed by rhodium carbonyl complexes tolerated a number of functional groups, including acetate esters, benzyl ethers, acetals, tosylamides, and allyl- and benzylamines (Table 3, entries 6-14). The reaction of diallyl-2-propynylamine is noteworthy as this transformation displayed high selectivity for cyclization of the enyne moiety rather than the diene moiety (Table 3, entry 9). Rhodium-catalyzed enyne cyclization/hydrosilylation tolerated substitution at the alkyne carbon (Table 3, entry 5) and, in some cases, at both the allylic and terminal alkenyl carbon atoms (Equation (7)). 

Shibata and co-workers have reported an effective protocol for the cyclization/hydrosilylation of functionalized eneallenes catalyzed by mononuclear rhodium carbonyl complexes.For example, reaction of tosylamide 13 (X = NTs, R = Me) with triethoxysilane catalyzed by Rh(acac)(GO)2 in toluene at 60 °G gave protected pyrrolidine 14 in 82% yield with >20 1 diastereoselectivity and with exclusive delivery of the silane to the G=G bond of the eneallene (Equation (10)). Whereas trimethoxysilane gave results comparable to those obtained with triethoxysilane, employment of dimethylphenylsilane or a trialkylsilane led to significantly diminished yields of 14. Although effective rhodium-catalyzed cyclization/hydrosilylation was restricted to eneallenes that possessed terminal disubstitution of the allene moiety, the protocol tolerated both alkyl and aryl substitution on the terminal alkyne carbon atom and was applicable to the synthesis of cyclopentanes, pyrrolidines, and tetrahydrofurans (Equation (10)). 

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