Ketone, diisopropyl

Actinide ions form complex ions with a large number of organic substances (12). Their extractabiUty by these substances varies from element to element and depends markedly on oxidation state. A number of important separation procedures are based on this property. Solvents that behave in this way are thbutyl phosphate, diethyl ether [60-29-7J, ketones such as diisopropyl ketone [565-80-5] or methyl isobutyl ketone [108-10-17, and several glycol ether type solvents such as diethyl CeUosolve [629-14-1] (ethylene glycol diethyl ether) or dibutyl Carbitol [112-73-2] (diethylene glycol dibutyl ether). 

If cyclic ketones are monosubstituted in the a-position, their rates of reaction decrease as compared to the rate for the parent ketone (9,41). More highly substituted ketones (e.g., diisobutyl ketone, diisopropyl ketone) can be caused to react using newer preparative techniques (39,43,44, see Section VII). Monosubstituted acetones often can give selfcondensation products, but the recent literature (13,39,43) contains reports of the successful formation of the enamines of methyl ketones. 

A reagent more reactive than tris(dimethylamino)arsine employed by Weingarten and White 39) was tetrakis(dimethylamino)titanium (145). With this compound it was possible to prepare N,N-dimethyl(l-isopropyl-2-methylpropcnyl)amine (147) from diisopropyl ketone. Weingarten and White 39) have suggested a possible mechanism for this reaction (see p. 88). If benzaldehyde 39,111), formaldehyde 111), or acetaldehyde 39) is used, the corresponding gem diamine or aminal (143) is formed. 

The McMurry procedure is a valuable method for the synthesis of highly substituted, strained alkenes such compounds are difficult to prepare by other methods. Diisopropyl ketone 6 can be coupled to give tetraisopropylethene 7 in 87% yield attempts to prepare tetra-t-butylethene however were not successful. ... 

The addition of HCN to aldehydes or ketones produces cyanohydrins. This is an equilibrium reaction. For aldehydes and aliphatic ketones the equilibrium lies to the right therefore the reaction is quite feasible, except with sterically hindered ketones such as diisopropyl ketone. However, ketones ArCOR give poor yields, and the reaction cannot be carried out with ArCOAr since the equilibrium lies too far to the left. With aromatic aldehydes the benzoin condensation (16-54) competes. With oc,p-unsaturated aldehydes and ketones, 1,4 addition competes (15-33). Ketones of low reactivity, such as ArCOR, can be converted to cyanohydrins by treatment with diethylaluminum cyanide (Et2AlCN see OS VI, 307) or, indirectly, with cyanotrimethylsilane (MesSiCN) in the presence of a Lewis acid or base, followed by hydrolysis of the resulting O-trimethylsilyl cyanohydrin (52). The use of chiral additives in this latter reaction leads to cyanohydrins with good asymmetric... 

Methyl ethyl ketone Diethyl ketone Diisopropyl ketone Di-f-butyl ketone Benzophenone... 

First the interaction of selected tetramethylpiperidine (TMP) derivatives with radicals arising from Norrish-type I cleavage of diisopropyl ketone under oxygen was studied. These species are most probably the isopropyl peroxy and isobutyryl peroxy radicals immediately formed after a-splitting of diisopropyl ketone and subsequent addition of O2 to the initially generated radicals. Product analysis and kinetic studies showed that the investigated TMP derivatives exercise a marked controlling influence over the nature of the products formed in the photooxidative process. The results obtained point to an interaction between TMP derivatives and especially the isobutyryl peroxy radical. 

Diisopropyl ketone photolysis under exclusion of oxygen... 

Diisopropyl ketone photolysis in the presence of oxygen and IZNO as additive... 

In the presence of nitroxide I, diisopropyl ketone photooxidation takes a course differing considerably from that without this additive (Fig. 5). In this case high yields of isobutyric acid and acetone were obtained, presumably as products arising from the postulated peroxy radicals c and d. On the other hand, the formation of isopropanol is almost completely suppressed. 

Irradiation of diisopropyl ketone under oxygen in the presence of the hindered piperidine II likewise results in formation of isobutyric acid, acetone and small amounts of isopropanol. At the same time the amine is quantitatively oxidized to the corresponding nitroxide I (Fig. 7, reaction (17)) ... 

Solvent-free hydrogenations of 1-octene, 2-pentene, cyclohexene, and styrene were carried out with catalyst loadings as low as 0.05 mol.% of the dimer, in some cases with TOF values as high as 6000 IT1 [71]. Total turnover numbers of almost 2000 were obtained in most of these cases. Solvent-free hydrogenation of ketones such as Et2C=0, cyclohexanone, and diisopropyl ketone were also reported at the same temperature and H2 pressure, but with somewhat lower TOFs for the hydrogenation of C=0 compared to C=C hydrogenations. 

Diisopropyl ketone, adipic acid solubility, l 555t... 

Scheme 6.23 3-Methylenecyclobutanol derivatives from the interception of the methyl-substituted 1,2-cyclohexadienes 74 and 82 by the enolates of cyclohexanone and diisopropyl ketone, respectively.

DIISOPROPYL KETONE 39.9665 -3.4805E+03 -1.1093E+01 -3.3888E-10 3.1900E... 

An interesting deoxygenation of ketones takes place on treatment with low valence state titanium. Reagents prepared by treatment of titanium trichloride in tetrahydrofuran with lithium aluminum hydride [205], with potassium [206], with magnesium [207], or in dimethoxyethane with lithium [206] or zinc-copper couple [206,209] convert ketones to alkenes formed by coupling of the ketone carbon skeleton at the carbonyl carbon. Diisopropyl ketone thus gave tetraisopropylethylene (yield 37%) [206], and cyclic and aromatic ketones afforded much better yields of symmetrical or mixed coupled products [206,207,209]. The formation of the alkene may be preceded by pinacol coupling. In some cases a pinacol was actually isolated and reduced by low valence state titanium to the alkene [206] (p. 118). 

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