Platinum aliphatic ketones

Stability toward reduction makes hydrogen fluoride a good medium for different hydrogenation processes [1, 2] It is a useful solvent for the hydrogenation of benzene in the presence of Lewis acids [f ] Anhydrous hydrofluonc acid has pronounced catalytic effect on the hydrogenations of various aromatic compounds, aliphatic ketones, acids, esters, and anhydrides in the presence of platinum dioxide [2] (equations 1-3)... 

These results illustrate the practicality of preparing trialkylamines by the reductive alkylation of dialkylamines with aliphatic ketones. Excellent yields are obtained, particularly with the more reactive and less hindered ketones, such as cyclohexanone and acetone, and with the less hindered secondary amines. Platinum sulfide, or other platinum metal sulfides, are the catalysts of choice when more hindered reagents require more severe operating conditions. 

Rhenium sulfide was the most active and hydrogenated excess ketone to the corresponding alcohols. The platinum metal sulfides were found to be more active than the base metal sulfides and highly selective for the formation of (V-alkylarylamines. They usually produce a pure product with little or no side reactions, require no excess above the stoichiometric amount of ketone, and are active at relatively low pressures of hydrogen. An example with (V-phenyl-p-phcnylencdiaminc is shown in eq. 6.15.37 Platinum metal sulfides may also be used for the reductive alkylation of aliphatic amines and their nitroalkane precursors with aliphatic ketones. 

The majority of aliphatic ketones give the secondary alcohol on reduction at electrodes of carbon, mercury, lead, or platinum. The usual choice of electrolyte has been dilute sulfuric acid, acetate buffer, or a neutral salt solution, which will become alkaline during the course of reaction that consumes protons. Relatively few studies have been recorded of the isomer ratio obtained by reduction of open chain ketones with a prochiral center adjacent to the carbonyl function [32,33]. Results are collected in Table 2, and one aromatic carbonyl compound is included here for convenience. In general, the erythro-alcohol is favored and in an excess over that present in the equilibrium mixture [32,33]. These results are explained in terms of adsorption of intermediates at the electrode surface. For many of the examples in Table 2, the total yield of alcohol is low and this result is not generally typical of aliphatic carbonyl compounds, as can be seen from Table 3. 

Ruthenium-on-carbon in aqueous ethanol or platinum oxide also is used but to a much lesser extent than Pd. Palladium shows a low activity for hydrogenation of nonactivated aliphatic ketones, but all the platinum metals can be used in addition to Cu chromite and Ni catalysts. Platinum catalysts have been widely used, platinum-on-carbon in aqueous acid is satisfactory. Rhodium is active under mild conditions and leads to a-hydroxy steroids in excellent yields ... 

Activated easily enolizable aliphatic ketones, such as j8-diketones, j8-ketoamides, and /3-ketoesters, are extensively hydrogenolyzed. Hydrogenolysis depends on the catalyst type, amount of catalyst, solvent, and substrate structure. The methylene compound is favored in acetic acid, alcohols, and H2O, with larger amount of catalyst and Pt is often used. For instance, hydrogenation of cohulupone 1 over platinum oxide in methanol affords mainly 2 [equation (d)]. ... 

Using platinum oxide as catalyst, aliphatic ketones in HF are reduced by hydrogen to hydrocarbons. Rearrangements typical of carbonium ion intermediates are observed. "... 

Ruthenium is commonly used with other platinum metals as a catalyst for oxidations, hydrogenations, isomerizations, and reforming reactions. The synergetic effect of mixing ruthenium with catalysts of platinum, palladium, and rhodium lias been found for the hydrogenations of aromatic and aliphatic nitro compounds, ketones, pyndine, and nitriles. 

Lower aliphatic amines are widely used as intermediates for the synthesis of herbicides, insecticides and drugs or can be applied as rubber accelerators, corrosion inhibitors, surface active agents etc. [l]. The most widespread method for the preparation of lower aliphatic amines involves the reaction of ammonia with an alcohol or a carbonyl compound in the presence of hydrogen. The most common catalysts used for reductive amination of alcohols, aldehydes and ketones contain nickel, platinum, palladium or copper as active component [ I — 3 ]. One of the most important issues in the reductive amination is the selectivity control as the product distribution, i.e. the ratio of primary to secondary or tertiary amines, is strongly affected by thermodynamics. 

There are many examples of the preparation of tertiary aliphatic amines by the reductive alkylation of dialkylamines or secondary non-aromatic heterocyclic amines with ketones using platinum5-13, palladium12"17, mixtures of platinum and palladium18,and nickel12. 13. 9-22 catalysts. 

Malz, Jr. and Greenfield studied the preparation of tertiary amines by reductive alkylation of aliphatic secondary amines with ketones, using platinum metals and their sulfides as catalysts.40 Excellent yields of tertiary amines were obtained with unhindered ketones, such as cyclohexanone and acetone, and relatively unhindered secondary amines. In this study, 5% Pd-C and various transition metal sulfides were compared in the reductive alkylation of dibutylamine with cyclohexanone. By using the reaction conditions suitable to each catalyst, excellent yields of tertiary amines were obtained, as shown in Table 6.5. Approximately 5-15% of the excess cyclohex-... 

Unsymmetrical secondary amines are readily prepared in good yields by the catalytic reduction of Schiff bases at moderate temperatures in high-or low-pressure equipment. Many examples have been cited. The intermediate imines are prepared from primary amines and aldehydes—very seldom from ketones—and may be used without isolation (cf. method 431). For the preparation of aliphatic amines, e.g., ethyl-w-propylamine and n-butylisoamylamine, a prereduced platinum oxide catalyst is preferred with alcohol as the solvent. Schiff bases from the condensation of aromatic aldehydes with either aromatic or aliphatic amines are more readily prepared and are reduced over a nickel catalyst. In this manner, a large number of N-alkylbenzylamines having halo, hydroxyl, or methoxyl groups on the nucleus have been made. Reductions by means of sodium and alcohol and lithium aluminum hydride have also been described,... 

Among the aliphatic alcohols, oxidation of methanol has been studied most extensively [122-125]. At a platinum anode in acidic aqueous solutions, methanol oxidizes completely to CO2. Higher primary alcohols oxidize to aldehydes and acids under these conditions, though detailed mechanistic studies are lacking [126,127]. Anodic oxidation of secondary alcohols in aqueous acid leads to the corresponding ketones in high yield, but the reaction has received little attention over the years [126,128]. Indirect oxidation methods employing mediators are of considerable interest in this area and are treated elsewhere. 

The extent to which secondary and tertiary amines are formed by reductive alkylation is controlled to some degree by the steric bulk of the amine and the carbonyl compound. The more hindered the system, the higher the temperature and hydrogen pressure needed to affect the reaction. While the reductive alkylation of secondary aliphatic amines with formaldehyde takes place under mild conditions (Eqn.l9.52X N,N-dimethylaniline was prepared by reductive alkylation over palladium at 120°C and 15 atmospheres pressure (Eqn. 19.53). 153 54 Reductive alkylation of aniline with acetone over palladium gave a 67% yield of the monoalkylaniline at 100°C and 40 atmospheres pressure but secondary amine formation using the more sterically accessible ketones, 2-tetralone or 2-indanone, took place at room temperature and 4 atmospheres pressure (Eqn. 19.54). 55 Palladium was the preferred catalyst in these reactions since with platinum or rhodium ring hydrogenation was also observed. 54,155... 

Oximes of aliphatic aldehydes and ketones are hydrogenated to TV-alkyl-hydroxylamines in the presence of platinum black in aqueous-alcoholic hydrochloric acid 90 also a mixture of the ketone and hydroxylamine hydrochloride may be hydrogenated.91 However, with arylalkyl and aryl ketones the latter method yields amines. 

For aliphatic aldehydes and ketones, reduction to the alcohol can be carried out under mild conditions over platinum or the more-active forms of Raney nickel. Ruthenium is also an excellent catalyst for reduction of aliphatic aldehydes and can be used to advantage with aqueous solutions. Palladium is not very active for hydrogenation of aliphatic carbonyl compounds, but is effective for the reduction of aromatic aldehydes and ketones excellent yields of the alcohols can be obtained if the reaction is interrupted after absorption of one mole of hydrogen. Prolonged reaction, particularly at elevated temperatures or in the presence of acid, leads to hydrogenolysis and can therefore be used as a method for the reduction of aromatic ketones to methylene compounds. 

Catalytic hydrogenation of both aromatic and aliphatic aldehydes and ketones with hydrogen gas (H2) over platinum (Pt) and nickel (Ni) catalysts to produce the cor-... 

Carbonyl compounds, especially aldehydes and ketones, regardless of whether they are aliphatic, aromatic, heteroaromatic, or a,g-unsaturated have been investigated mostly at mercury electrodes as regards their reduction mechanism. It follows from literature, however, that they can be reduced at copper, silver, platinum, tin, nickel, aluminium, zinc or carbon cathodes. The mechanisms differ strongly being a function of the electrode material, of the solution composition and of the reducible carbonyl compound ... 

Carl Ludwig Paal and others used colloidal platinum and palladium catalysts in liquid phase hydrogenation reactions at low temperatures. Aromatic and unsaturated aliphatic compounds such as aldehydes or ketones were easily hydrogenated by either platinum or palladium. Aladir Skita collaborated with Paal in publishing a patent that described some of this work. The colloidal metals could be stabilized by the use of albumen from egg whites, but they were not really practicable and it was difficult to separate them from products. An outline of an early colloidal catalyst preparation is given in Table 3.4. 

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