Allylic alcohols ruthenium hydrogenation

D KR of allylic alcohols can be also performed using ruthenium complexes for the racemization that occurs through hydrogen transfer reactions (vide infra) [16]. 

Complexes containing one binap ligand per ruthenium (Fig. 3.5) turned out to be remarkably effective for a wide range of chemical processes of industrial importance. During the 1980s, such complexes were shown to be very effective, not only for the asymmetric hydrogenation of dehydroamino adds [42] - which previously was rhodium s domain - but also of allylic alcohols [77], unsaturated acids [78], cyclic enamides [79], and functionalized ketones [80, 81] - domains where rhodium complexes were not as effective. Table 3.2 (entries 3-5) lists impressive TOF values and excellent ee-values for the products of such reactions. The catalysts were rapidly put to use in industry to prepare, for example, the perfume additive citronellol from geraniol (Table 3.2, entry 5) and alkaloids from cyclic enamides. These developments have been reviewed by Noyori and Takaya [82, 83]. 

BINAP (40a) was first reported as a ligand in an enantioselective hydrogenation in 1980 [172], and provides good selectivity for the reductions of dehydroamino acid derivatives [173], enamides, allylic alcohols and amines, and a,p-unsaturated acids [4, 9, 11, 12, 174, 175]. The fame of the ligand system really came with the reduction of carbonyl groups with ruthenium as the metal [11, 176]. The Rh-BINAP systems is best known for the enantioselective isomerizations... 

This finding is the consequence of the distribution of various ruthenium(II) hydrides in aqueous solutions as a function of pH [RuHCl(mtppms)3] is stable in acidic solutions, while under basic conditions the dominant species is [RuH2(mtppms)4] [10, 11]. A similar distribution of the Ru(II) hydrido-species as a function of the pH was observed with complexes of the related p-monosulfo-nated triphenylphosphine, ptpprns, too [116]. Nevertheless, the picture is even more complicated, since the unsaturated alcohol saturated aldehyde ratio depends also on the hydrogen pressure, and selective formation of the allylic alcohol product can be observed in acidic solutions (e.g., at pH 3) at elevated pressures of H2 (10-40 bar [117, 120]). (The effects of pH on the reaction rate of C = 0 hydrogenation were also studied in detail with the [IrCp (H20)3]2+ and [RuCpH(pta)2] catalyst precursors [118, 128].)... 

ASYMMETRIC HYDROGENATION OF ALLYLIC ALCOHOLS USING BINAP-RUTHENIUM COMPLEXES (S)-(-)-CITRONELLOL (6-Octen-1-ol, 3,7-dimethyl, (S)-)... 

Allylic alcohols (Continued) ruthenium hydrogenation, 39 titanium epoxidation, 10, 139, 141, 289, 310, 361... 

The same concept is applicable to allylic alcohols, ketones, or ketoximes. Enol acetates or ketones were successfully converted in multi-step reactions to chiral acetates in high yields and optical yields through catalysis by Candida antarctica lipase B (CALB, Novozyme 435) and a ruthenium complex. 2,6-Dimethylheptan-4-ol served as a hydrogen donor and 4-chlorophenyl acetate as an acyl donor for the conversion of the ketones (Jung, 2000a). 

This ligand, MeO-BIPHEP (96a), has shown similar reactivities and enantioselectivities to catalysts that contain BINAP.117 Ruthenium catalysts that contain MeO-BIPHEP have been used in several asymmetric hydrogenations from bench scale to multi-ton scale, which include the large-scale preparation of a P-keto ester, an aryl ketone, allylic alcohol, and several oc,P-unsaturated carboxylic acid substrates, which are shown in Figure 12.5. 

Ruthenium and rhodium complexes that contain TMBTP have shown utility in the asymmetric hydrogenation of allylic alcohols,155,156 P-keto esters,155,157 and a,P-unsaturated carboxylic acids.155... 

Asymmetric hydrogenation of allylic alcohols (14, 39-40).1 Mammalian dol-ichols (2) are terminal dihydropolyisoprenols which are involved in glycoprotein synthesis. They contain one terminal chiral primary allylic alcohol group. The polyprenols 3 present in plants correspond to dolichols except that they lack the terminal double bond considered to be (Z). They can be obtained by hydrogenation of 2 catalyzed by (bistrifluoroacetate)ruthenium(II) and (S)-l, which affects only the terminal double bond to provide (S)-3 in >95% ee. 

BINAP-ruthenium(II) is particularly good at catalysing the hydrogenation of allylic alcohols, and of a,(3-umaturated carboxylic adds to give acids bearing a stereogenic centres (like naproxen above). 

Allylic alcohols are isomerized via direct interaction of the ruthenium atom with alcohol. /3-Elimination of ruthenium hydride from metal alkoxide yields a ruthe-nium-enone species C which undergoes insertion of the olefinic moiety into the Ru-H to form an oxyallylic intermediate D. As a result, the hydrogen atom shifts from the a- to y-position of the allylalcohol. Protonolysis of the oxyallylic species leads to a saturated carbonyl compound and cationic unsaturated species, [CpRu(PPh3)2] A. 

The same catalyst precursor, generated from [(EDTA)RuCI] which is also water soluble, was used for the hydroformylation of allylic alcohol under the same reaction conditions (//). At 50 bar and 130°C, in water as solvent, 4-hydroxybutanal was produced [Eq. (5)], together with about 2% of formaldehyde. However, the reaction proceeded further to give butane-1,4-diol by hydrogenation and y-butyrolactone as well as dihydrofuran by cyclization [Eq. (6)]. The same catalytic cycle as that proposed in Scheme 3 can be considered. A kinetic investigation revealed a first-order dependence on the ruthenium complex concentration and on the allyl alcohol... 

Ruthenium(binap) complexes effectively catalyze asymmetric hydrogenation of a-amidocinnamic acids [172], allylic alcohols [173] and acrylic acids with almost quantitative enantiomeric excess [174]. For example, one of the largest-selling anti-inflammatory agents, Naproxen should be supplied as the enantiomerically pure 5-isomer, because the R-isomer is expected to be toxic to the liver. Asymmetric hydrogenation of the precursor by RuCL[(5)- binap] produces 5-Naproxen with 96-98 % ee (eq (47)) [175-176]. 

The resolution of racemic secondary allyl alcohols can be performed in the presence of certain ruthenium chiral catalysts through enantioselective asymmetric hydrogenation [811, 881], Chiral poisoning also works in such kinetic resolutions. For example, hydrogenation of 2-cyclohexenol under ( )-binap-Ru catalysis in the presence of (II , 25)-ephedrine 1.61 (10 equiv) provides unreacted (J )-2-cydo-hexenol in 95% ee after 60% conversion [857],... 

A further interesting contrast between rhodium and ruthenium hydrogenation catalysts in kinetic resolution is provided. Most of the published work for the latter relates to ruthenium (BINAP) chemistry but a wider spectrum of allylic alcohols is reduced with satisfactory selectivity the need for an electron-withdrawing group at the a -position is no longer evident. Where a direct comparison can be drawn between rhodium(BINAP) and ruthenium(BlNAP) (Table 6, entry 1), the reduction with a given enantiomer of catalyst gives the opposite enantiomer of a... 

Allylic alcohols, such as gcraniol (42) and nerol (43), can be converted to citronellol (44) with high efficiency and excellent enantioselectivity by hydrogenation using ruthenium BINAP complexes108 or related catalysts76. Enantiomeric excesses between 96-98%, essentially quantitative yields, and very high substrate/catalyst ratios (up to 50000 1) are attractive attributes of... 

Water and supercritical carbon dioxide form an excellent medium for hydrogenation of unsaturated aldehydes to allylic alcohols with ruthenium(lll) chloride and a water-soluble triarylphosphine, because the limitation pertaining to gas-liquid-liquid mass transfer is eliminated due to the very high. solubility of reactant gas. 

Asymmetric Hydrogenation of Allylic Alcohols Using BINAP-Ruthenium Complexes (S)-(-)-Citronellol. 

Isomerization of allylic alcohols to ketones. l-Alkene-3-ols in organic solvents are isomerized to saturated ketones in high yield by this ruthenium complex by intramolecular transfer of hydrogen ... 

Allylic alcohols make good substrates for ruthenium/BINAP-catalysed hydrogenation. Geraniol (2.81) and nerol (2.82) are (E) and (Z) isomers, and these substrates afforded opposite enantiomers of the product citronellol (2.83). 

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