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Coupling triethylsilane

The reaction of thiyl radicals with silicon hydrides (Reaction 8) is the key step of the so-called polariiy-reversal catalysis in the radical chain reduction. The reaction is strongly endothermic and reversible with alkyl-substituted silanes (Reaction 8). For example, the rate constants fcsH arid fcgiH for the couple triethylsilane/ 1-adamantanethiol are 3.2 x 10 and 5.2xlO M s respectively. [Pg.125]

Berry has recently reported an example of catalytic arene activation and functionalization. This report involves either Cp Rh(SiEt3)2H2 or (r 6-arene) Ru(SiEt3)2H2 as catalyst and couples triethylsilane with an arene. t-Butylethyl-ene serves as a hydrogen acceptor (Eq. 31). No intermediates are observed, and a carbosilane dimer is also formed as a significant fraction of the total product [118]. [Pg.39]

The arylcopper reagents couple with 1-iodoarylacetylenes to give the unsym-metrical diarylacetylenes [25(S] (equation 176) Reaction with tetrabromoethyl- ene gives bis(pentafluorophenyl)acetylene in 66% yield [25S] (equation 177) Pen-tafluorophenyl copper couples with (bromoethynyl)triethylsilane to give C6F5C=CSi(C2H5)3 in 85% yield [259]... [Pg.713]

Corriu et al. have reported that the coupling reaction of 2-(iV,iV-dimethylaminomethyl)phenyllithium with (McvSi)vSiCI 53 affords 2-(iV,iV-dimethylaminomethyl)-l-[tris(trimethylsilyl)silyl]benzene 894. No evidence has been found that the intramolecular iV-ligand coordinates to the silicon atom of 894. Upon UV irradiation, the trisilane forms a transient silyene 895, which has been trapped with 2,3-dimethyl-2,3-butadiene and triethylsilane to give the oligosilanes 896 and 897 as well as 898-900, (Scheme 126).859 Apparently, the bulk on the two ligands is insufficient to provide kinetic stabilization of the silylene intermediate 895. [Pg.492]

Alternatively to using prelipidated building blocks palmitoylation on resin is possible with the hydrazine linker. In Scheme 27 the synthesis route for the palmitoylated and farnesylated N-Ras peptide 78 is shown. Here the initial loading of trityl-protected cysteine to the hydrazine linker was mediated by A,A-diisopropylcarbodiimide (DIG) and HOBt. After Fmoc removal the proline was coupled using HBTU and HOBt. The trityl-protected dipeptide 75 was subsequently S-deprotected using TFA with triethylsilane (TES) as a scavenger. Farnesylation of the free thiol was achieved with an excess of farnesyl bromide. [Pg.557]

Falck has recently reported dehydrogenative silylation of heteroarenes with triethylsilane (18) [97]. Coupling with the Si-H bond of triethylsilane, rather than the disilane Si-Si bond, in conjunction with the use of norbomene that presumably acts as a hydrogen acceptor, gives good yields with indoles, thiophenes, and furans, under relatively mild condition (80°C). Unlike the reaction shown in Scheme 7, silylation of indole did not require protection of the N-H group. [Pg.153]

The synthesis of the right-hand fragment of ziprasidone started with a Wolff-Kishner reduction of isatin 43 to give the oxmdole 44 (Scheme 14). Friedel-Crafts acylation with chloroacetyl chloride afforded aryl ketone 45, which was reduced with triethylsilane in trifluoroacetic acid to the phenethyl chloride 46. The two fragments were joined by alkylation of 40 with 46 in the presence of Nal and Na2CO3 to give ziprasidone (4) in low yield. The yield of the coupling step was improved dramatically when the reaction was conducted in water (Scheme 15). [Pg.102]

A palladium-catalysed reduction of ethyl thiolesters to aldehydes with triethylsilane has been proposed by Fukuyama [2611. The reaction, coupled with a mild conversion of carboxylic acids to thiolesters (see [261], footnote 2), affords a versatile method for the overall transformation of... [Pg.149]

McMurray [151] has described the acid-assisted cleavage of the N]-C4 bond in trans 4-hydroxyphenyl p-lactams. The ring opening reaction may proceed with concomitant reduction or formation of carbon-carbon coupling products, as a function of the reagent employed. For instance, Scheme 60, treatment of 196 with 4 equivalents of triethylsilane in neat trifluoroacetic acid led to compound 197. On the contrary, treatment with anisole in trifluoroacetic acid led to compound 198. Unfortunately, no data are provided by authors regarding process yield or final diastereomeric ratio. [Pg.247]

The first example of silylation of C-H bonds in arenes with hydrosilanes was reported by Curtis [2]. Later, silylation of C-H bonds with triethylsilane using a rhodium catalyst was reported (Scheme 3) [3, 4], The reaction of arenes with bis(hydrosilane) using a platinum catalyst involves a bis(silyl)platinum species in the coupling reaction (Scheme 3) [5]. In these non-chelation-assisted reactions possible regioisomers should be formed. [Pg.133]

Evidence that this reduction proceeds mainly via an N-acyl iminium ion intermediate 120 was obtained by carrying out the triethylsilane reduction of 108 in deuterated trifluoroacetic acid (Scheme 49). As before, two C-4 epimeric protected kainoid analogues 121 and 122 were obtained, H NMR showing loss of the C-4 proton in both products accompanied by a simplification in the spin-spin coupling pattern of the C-5 protons.73 A close examination of the 2H NMR spectrum of each diastereoisomer did, however, reveal a trace of deuteration at C-5 indicating that a small percentage of the reduction also occurs via a benzylic carbocation intermediate 123 (Figure 12). [Pg.193]

The 29Si NMR spectrum of triethylsilane in both proton decoupled and proton coupled modes is presented next in Figure 6.9. The proton decoupled spec-... [Pg.326]

The coupling of indoles 722 with isonicotinaldehyde 723 gives 3-indolyl 4-pyridinyl methanols 724, which upon treatment with triethylsilane in the presence of CF3CO2H afford 3-(4-pyridinyl)methylindoles 725 in 64-76% overall yield (Scheme 143) <2001TL7333>. Thus, treatment of 5-fluoroindole 722 (R = F, R = H) with aldehyde 723... [Pg.151]

The mechanism for this palladium-catalyzed cross-coupling reaction comprises the initial oxidative addition of the electrophile 37 to the palladium(O) catalyst followed by transmetallation of triethylsilane to yield the corresponding bis(organo)palladium(II) complex 39, which then undergoes reductive elimination to form the alkene 40 and to regenerate the palladium(O) catalyst. [Pg.164]

The chemistry of )9-(thiocarbonyloxy)alkyl radicals stands in complete contrast to that of the (acyloxy)alkyl radicals, with elimination, while not the rule, being the norm [I]. The difference between the acyloxy and thiocarbonyloxy series is likely a consequence of the much weaker thiocarbonyl bond and the related higher stability of sulfur-centered radicals. The method has been developed in combination with the Barton deoxygenation method (Volume 1, Chapter 1.6) as a means of converting a vicinal diol, via the dixanthate, into an alkene (Scheme 33) [60-62]. Tributyltin hydride has been the reagent of choice for this reaction but it may also be conducted with the triethylsilane/benzoyl peroxide couple [63] and, doubtless, tris(trimethylsilyl)silane. [Pg.701]

FIGURE 7.9. The proton-decoupled 29Si NMR spectrum (59.6 MHz) of triethylsilane in CDCI3. The proton-coupled spectrum is shown as an inset. [Pg.290]

See other pages where Coupling triethylsilane is mentioned: [Pg.270]    [Pg.19]    [Pg.80]    [Pg.269]    [Pg.181]    [Pg.37]    [Pg.307]    [Pg.125]    [Pg.327]    [Pg.328]    [Pg.315]    [Pg.62]    [Pg.198]    [Pg.82]    [Pg.342]    [Pg.713]    [Pg.587]    [Pg.240]    [Pg.241]    [Pg.416]    [Pg.318]    [Pg.1094]    [Pg.631]    [Pg.281]    [Pg.644]    [Pg.289]    [Pg.446]    [Pg.681]   
See also in sourсe #XX -- [ Pg.494 ]

See also in sourсe #XX -- [ Pg.510 ]



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