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Ruthenium, catalyst Subject

Only a few publications dealing with this subject can be found in the literature. Hydrogenation of diketo esters A with chirally modified ruthenium catalysts resulted in mixtures of syn- and anti-dihydroxy esters C with varying enantiomeric excesses [5], A notable exception to this is represented by the recent work of Car-pentier et al., who succeeded in controlling the reduction of methyl 3,5-dioxohex-anoate at the initial step, namely the reduction of the P-keto group. The enantiomeric excess achieved was, nevertheless, limited to 78% at best [5a]. [Pg.387]

In some cases the so-called "Steady-State Isotopic Transient Kinetic Analysis" (SSITKA) was used for detailed investigations of reaction mechanisms. Shannon and Goodman [123] present an extensive review of this subject. Hinrichsen et al. [124] employed temperature programmed desorption to study the ammonia synthesis on ruthenium catalysts. [Pg.52]

Therefore, one key subject for activated carbon supported ruthenium catalyst study is to solve the loss of activated carbon due to methanation and many scientists have done a lot of studiesd d7,39,iio,i2i,220 current solutions way includes (i) Graphitization of activated carbon and using promoter can inhibit the methanation (ii) Seek for new support that can replace the activated carbon such as metal oxide. [Pg.522]

In 2009, Buchmeiser and co-workers reported the synthesis of a novel ruthenium complex 54 based on a seven-membered NHC ligand [68] (Fig. 3.22). To examine the catalytic activity of complex 54 in the RCM reaction, the authors subjected the complex to a series of typical RCM reactions by using substrates 1, 3, and 5. Pre-catalyst 54 showed only moderate reactivity with 1 and 3 and no reaction occurred with 5. [Pg.77]

Carbon-supported Ru-Sn catalyst Ru and Sn Mossbauer measurements were performed to investigate catalysts of ruthenium and tin supported on activated carbon (Ru-Sn/C). The samples were subjected to different reducing and oxidizing treatments. The presence of tin leads to a substantial increase of the Lamb-Mossbauer factor of the metallic Ru-particles showing that tin strengthens the attachment of the particles to the support. The close contact between the two metals appears to be decisive for the formation of catalytically active sites (Ru-Sn and Ru-SnOj,-)... [Pg.284]

The most widely used method for adding the elements of hydrogen to carbon-carbon double bonds is catalytic hydrogenation. Except for very sterically hindered alkenes, this reaction usually proceeds rapidly and cleanly. The most common catalysts are various forms of transition metals, particularly platinum, palladium, rhodium, ruthenium, and nickel. Both the metals as finely dispersed solids or adsorbed on inert supports such as carbon or alumina (heterogeneous catalysts) and certain soluble complexes of these metals (homogeneous catalysts) exhibit catalytic activity. Depending upon conditions and catalyst, other functional groups are also subject to reduction under these conditions. [Pg.368]

Representatives of the bridged sulfone system 70 have been subjected to ruthenium catalysed ring-closing metathesis reactions (Grubbs catalyst) and shown to afford, in low yields, a few selected cyclic dimers and trimers, of all the possibilities available. The diastereoselectivities observed were rationalised in terms of kinetic control involved with internal ruthenium/sulfonyl oxygen coordination . [Pg.354]

The conversion of iron catalysts into iron carbide under Fischer-Tropsch conditions is well known and has been the subject of several studies [20-23], A fundamentally intriguing question is why the active iron Fischer-Tropsch catalyst consists of iron carbide, while cobalt, nickel and ruthenium are active as a metal. Figure 5.9 (left) shows how metallic iron particles convert to carbides in a mixture of CO and H2 at 515 K. After 0.5 and 1.1 h of reaction, the sharp six-line pattern of metallic iron is still clearly visible in addition to the complicated carbide spectra, but after 2.5 h the metallic iron has disappeared. At short reaction times, a rather broad spectral component appears - better visible in carburization experiments at lower temperatures - indicated as FexC. The eventually remaining pattern can be understood as the combination of two different carbides -Fe2.2C and %-Fe5C2. [Pg.143]

Tab. 8.1 summarizes the various substrates that were subjected to the rhodium-catalyzed reaction using a Rh-dppb catalyst system. Only ds-alkenes were cycloisomerized under these conditions, because the trans-alkenes simply did not react. Moreover, the formation of the y-butyrolactone (Tab. 8.1, entry 8) is significant, because the corresponding palladium-, ruthenium-, and titanium-catalyzed Alder-ene versions of this reaction have not been reported. In each of the precursors shown in Tab. 8.1 (excluding entry 7), a methyl group is attached to the alkene. This leads to cycloisomerization products possessing a terminal alkene, thus avoiding any stereochemical issues. Also,... [Pg.153]

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See also in sourсe #XX -- [ Pg.1565 ]



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