Ketone bond

Other bonds that merit attention are those connecting C(7) through C(ll). These could be formed by one of the many methods for the synthesis of ketones. Bond disconnections at carbonyl centers can involve the 0=C-C(a) (acylation, organometallic addition), the C(a)-C((3) bond (enolate alkylation, aldol addition), or C((3)-C(7) bond (conjugate addition to enone). 

Although ketone bonding is normally through oxygen, if-complexes with C, O bonding can be formed. With certain Pt compounds, acetone can form C-bonded acetonate species.101 Coupling of ketones can also occur under some conditions as with diethylketomalonate ... 

Asymmetric Transfer Hydrogenation of Imines. In spite of the great importance of optically active amines for pharmaceutical and agrochemical industries, the ATH of C=N imine bonds has been much less studied than that of ketone bonds (278,280,284,289,340). Cyclic imines are reduced with greater ee values than their acyclic counterparts. The existence of geometrical isomers for the latter is based on the encountered difference in selectivity. 

Third, the attentive reader will not have failed to note that both Section A (Oxidation of Aldehydes and Ketones) and Section B (Reduction of Aldehydes and Ketones) in this chapter involve addition to the carbonyl group (C=0). Thus, as shown in Section A, processes that result in oxidation of the carbonyl group (C=0) proceed from initial attack at the sp -hybridized carbon of the carbonyl (C=0) by an electron rich species. The xp -hybridized intermediate resulting from that attack is ultimately consumed when the carbon-hydrogen aldehydic (0=C-H) or the carbon-carbon (0=C-C) ketonic bond breaks. Similarly, in reduction (Section B), the processes involving hydride ion transfer are shown as attack of hydride (H ) donating species onto the xp -hybridized carbon of the carbonyl (C=0) with rehybridization at carbon to sp and eventual protonation at oxygen. 

Figure 5.291 left shows the influence of temperature on the formation of various oxidation products on the exterior pipe surface of non-stabilized MDPE-pipes. The exponential increase in oxidation products is caused by the autocatalytic process of thermal oxidation. The formation of ketone bonds proceeds ten times faster than the formation of other structures. The higher the load temperature, the faster oxidation takes place. Oxidation products increase faster on the exterior pipe surface than on the interior pipe surface. Figure 5.291 right. This is also the case for other temperatures. Oxidation on the interior pipe surface is limited to only a thin border layer (0.5-1 mm) for different temperatures [63] because of the low concentration of oxygen dissolved in water on the pipe inner surface. This concentration decreases even further with increasing temperature. 

The thermal properties and mechanical properties of PAEKs will be modified by changing number of phenyl, ether bond or ketone bond in constitutional unit of PAEKs. PEEK-PEEKK copol)uner could be synthesized by copolymerizing with 4,4 -difluorobenzo-phenone (DEB), l,4-bis(p-fluorobenzoyl)benzene (BFB) and hydro-quinone (HQ) according to Scheme 10.1 [23]. 

The results exhibited that the melting point of PEEK-PEEKK copolymers increased with the mole fraction of BFB because of increase of PEEK-PEEKK copolymers rigidity, in other words, the heat-resistance of copolymers increased by introducing more ketone bonds into copolymers. So the properties of PEEK-PEEKK copolymers could be optimized by adjusting the ratio of copolymerization monomers. 

One could find from Figure 10.2a and Figure 10.2b that the T of PEEK-PEDEK copolymers increased with increase of biphenyf content of copolymers, but the of PEEK-PEDEK copolymers firstly decreased with increase of biphenyl content until the biphenyl content increased 30% and then of PEEK-PEDEK copolymers gradually increased with increase of biphenyl content. The Tj change of PEEK-PEDEK copolymers was different from that of PEEK-PEEKK copolymers. This phenomenon maybe resulted from different link mode of phenyl, ether bond or ketone bond in polymer chain. 

The formation of ethyl isopropylidene cyanoacetate is an example of the Knoevenagel reaction (see Discussion before Section IV,123). With higher ketones a mixture of ammonium acetate and acetic acid is an effective catalyst the water formed is removed by azeotropic distillation with benzene. The essential step in the reaction with aqueous potassium cyanide is the addition of the cyanide ion to the p-end of the ap-double bond ... 

The addition of active methylene compounds (ethyl malonate, ethyl aoeto-acetate, ethyl plienylacetate, nltromethane, acrylonitrile, etc.) to the aP-double bond of a conjugated unsaturated ketone, ester or nitrile In the presence of a basic catalyst (sodium ethoxide, piperidine, diethylamiiie, etc.) is known as the Michael reaction or Michael addition. The reaction may be illustrated by the addition of ethyl malonate to ethyl fumarate in the presence of sodium ethoxide hydrolysis and decarboxylation of the addendum (ethyl propane-1 1 2 3-tetracarboxylate) yields trlcarballylic acid ... 

The main use of organocadmium compounds is for the preparation of ketones and keto-esters, and their special merit lies in the fact that they react vigorously with acid chlorides of all types but add sluggishly or not at all to multiple bonds (compare addition of Grignard reagents to carbonyl groups). Some t3rpical syntheses are ... 

Note that NaBH4 reduces aldehydes (and ketones) but not esters while L1A1H4 reduces just about all carbonyl compounds. Neither reagent reduces an isolated deuble bond. 

Analysis Another lactone FGl reveals the true TM (A). Our normal discormection a of an a,p-unsaturated carbonyl compound gives us the 1,5-dicarbonyl compound (B) and the ketone (C) clearly derived from phenol. Alternatively we could disconnect bond b to the keto-ester (D) with the further discormection shown ... 

That double bonded oxygen (a.k.a. ketone) is very amenable to attack and replacement and is the ideal stepping stone to final product. There are a variety of methods to accomplish this intermediate. Many of which Strike is now gonna iay on you ... 

The problem of the synthesis of highly substituted olefins from ketones according to this principle was solved by D.H.R. Barton. The ketones are first connected to azines by hydrazine and secondly treated with hydrogen sulfide to yield 1,3,4-thiadiazolidines. In this heterocycle the substituents of the prospective olefin are too far from each other to produce problems. Mild oxidation of the hydrazine nitrogens produces d -l,3,4-thiadiazolines. The decisive step of carbon-carbon bond formation is achieved in a thermal reaction a nitrogen molecule is cleaved off and the biradical formed recombines immediately since its two reactive centers are hold together by the sulfur atom. The thiirane (episulfide) can be finally desulfurized by phosphines or phosphites, and the desired olefin is formed. With very large substituents the 1,3,4-thiadiazolidines do not form with hydrazine. In such cases, however, direct thiadiazoline formation from thiones and diazo compounds is often possible, or a thermal reaction between alkylideneazinophosphoranes and thiones may be successful (D.H.R. Barton, 1972, 1974, 1975). 

Before we start with a systematic discussion of the syntheses of difunctional molecules, we have to point out a formal difficulty. A carbonmultiple bond is, of course, considered as one functional group. With these groups, however, it is not clear, which of the two carbon atoms has to be named as the functional one. A 1,3-diene, for example, could be considered as a 1,2-, 1,3-, or 1,4-difunctional compound. An a, -unsaturated ketone has a 1.2- as well as a 1,3-difunctional structure. We adhere to useful, although arbitrary conventions. Dienes and polyenes are separated out as a special case. a, -Unsaturated alcohols, ketones, etc. are considered as 1,3-difunctional. We call a carbon compound 1,2-difunctional only, if two neighbouring carbon atoms bear hetero atoms. 

The most general methods for the syntheses of 1,2-difunctional molecules are based on the oxidation of carbon-carbon multiple bonds (p. 117) and the opening of oxiranes by hetero atoms (p. 123fl.). There exist, however, also a few useful reactions in which an a - and a d -synthon or two r -synthons are combined. The classical polar reaction is the addition of cyanide anion to carbonyl groups, which leads to a-hydroxynitriles (cyanohydrins). It is used, for example, in Strecker s synthesis of amino acids and in the homologization of monosaccharides. The ff-hydroxy group of a nitrile can be easily substituted by various nucleophiles, the nitrile can be solvolyzed or reduced. Therefore a large variety of terminal difunctional molecules with one additional carbon atom can be made. Equally versatile are a-methylsulfinyl ketones (H.G. Hauthal, 1971 T. Durst, 1979 O. DeLucchi, 1991), which are available from acid chlorides or esters and the dimsyl anion. Carbanions of these compounds can also be used for the synthesis of 1,4-dicarbonyl compounds (p. 65f.). 

Terminal alkyne anions are popular reagents for the acyl anion synthons (RCHjCO"). If this nucleophile is added to aldehydes or ketones, the triple bond remains. This can be con verted to an alkynemercury(II) complex with mercuric salts and is hydrated with water or acids to form ketones (M.M.T. Khan, 1974). The more substituted carbon atom of the al-kynes is converted preferentially into a carbonyl group. Highly substituted a-hydroxyketones are available by this method (J.A. Katzenellenbogen, 1973). Acetylene itself can react with two molecules of an aldehyde or a ketone (V. jager, 1977). Hydration then leads to 1,4-dihydroxy-2-butanones. The 1,4-diols tend to condense to tetrahydrofuran derivatives in the presence of acids. 

The addition of acetylides to oxiranes yields 3-alkyn-l-ols (F. Sondheimer, 1950 M.A. Adams, 1979 R.M. Carlson, 1974, 1975 K. Mori, 1976). The acetylene dianion and two a -synthons can also be used. 1,4-Diols with a carbon triple bond in between are formed from two carbonyl compounds (V. Jager, 1977, see p. 52). The triple bond can be either converted to a CIS- or frans-configurated double bond (M.A. Adams, 1979) or be hydrated to give a ketone (see pp. 52, 57, 131). 

If a Michael reaction uses an unsymmetrical ketone with two CH-groups of similar acidity, the enol or enolate is first prepared in pure form (p. llff.). To avoid equilibration one has to work at low temperatures. The reaction may then become slow, and it is advisable to further activate the carbon-carbon double bond. This may be achieved by the introduction of an extra electron-withdrawing silyl substituent at C-2 of an a -synthon. Treatment of the Michael adduct with base removes the silicon, and may lead as well to an aldol addition (G. Stork, 1973, 1974 B R.K. Boeckman, Jr., 1974). 

The synthesis of spiro compounds from ketones and methoxyethynyl propenyl ketone exemplifies some regioselectivities of the Michael addition. The electrophilic triple bond is attacked first, next comes the 1-propenyl group. The conjugated keto group is usually least reactive. The ethynyl starting material has been obtained from the addition of the methoxyethynyl anion to the carbonyl group of crotonaldehyde (G. Stork, 1962 B, 1964A). 

Selective reduction of a benzene ring (W. Grimme, 1970) or a C C double bond (J.E. Cole, 1962) in the presence of protected carbonyl groups (acetals or enol ethers) has been achieved by Birch reduction. Selective reduction of the C—C double bond of an a,ft-unsaturated ketone in the presence of a benzene ring is also possible in aprotic solution, because the benzene ring is redueed only very slowly in the absence of a proton donor (D. Caine, 1976). 

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