Terminal methyl ketones

Highly substituted cyclohexanes and cyclopentanes have been prepared by means of a cascade process involving the use of a nitroalkene as Michael acceptor and an a-substituted p-ketoester incorporating a lateral p-substituent with a terminal methyl ketone moiety at the convenient position, ready to... 

A more active system working under less harsh conditions was obtained using (—)-sparteine as a bidentate ligand for Pd(II). A lower concentration of O2 can be used and the possible isomerization of terminal olefins is suppressed with the exclusive formation of terminal methyl ketones (Scheme 23.47). Enantiomerically-enriched protected alcohols bearing terminal alkenes provided the corresponding chiral methyl ketones without racemization, further emphasizing the potential synthetic utihty of the oxidation method. 

For molecules similar to safrole or allylbenzene we take the work done on any terminal alkene such as 1-heptene, 1 octene. Another term to look for is olefin which is a term for a doublebond containing species. What we then look for are articles about these olefins where the functional groups we are looking for are formed. Articles with terminology like methyl ketones from (P2P), ketones from , amines from etc. Or when we want to see about new ways to aminate a ketone (make final product from P2P) we look for any article about ketones where amines are formed. Sound like science fiction to you Well, how do you think we came up with half the recipes in this book It works ... 

Higher terminal alkenes are oxidized to methyl ketones and this unique oxidation of alkenes has extensive synthetic applications[23]. The terminal alkenes can be regarded as masked methyl ketones, which are stable to acids, bases, and nucleopliiles[24]. The oxidation of terminal alkenes to methyl ketones has been extensively applied to syntheses of many natural products[77]. 

Acetoxy-l,7-octadiene (40) is converted into l,7-octadien-3-one (124) by hydrolysis and oxidation. The most useful application of this enone 124 is bisannulation to form two fused six-membered ketonesfl 13], The Michael addition of 2-methyl-1,3-cyclopentanedione (125) to 124 and asymmetric aldol condensation using (5)-phenylalanine afford the optically active diketone 126. The terminal alkene is oxidi2ed with PdCl2-CuCl2-02 to give the methyl ketone 127 in 77% yield. Finally, reduction of the double bond and aldol condensation produce the important intermediate 128 of steroid synthesis in optically pure form[114]. 

Oxidation. The use of l,4-ben2oquinone in combination with paHadium(Il) chloride converts terminal alkenes such as 1-hexene to alkyl methyl ketones in high yield (81%) (32). The quinone appears to reoxidi2e the palladium. 

Methyl ketones are important intermediates for the synthesis of methyl alkyl carbinols, annulation reagents, and cyclic compounds. A common synthetic method for the preparation of methyl ketones is the alkylation of acetone derivatives, but the method suffers limitations such as low yields and lack of regioselectivity. Preparation of methyl ketones from olefins and acetylenes using mercury compounds is a better method. For example, hydration of terminal acetylenes using HgSO gives methyl ketones cleanly. Oxymercuration of 1-olefins and subsequent oxidation with chromic oxide is... 

A mixture of both possible ketones results when an unsymmetrically substituted internal alkyne (RC=CR ) is hydrated. The reaction is therefore most useful when applied to a terminal alkyne (RC=CH) because only a methyl ketone is formed. 

The hydroboration/oxidation sequence is complementary to the direct, mercury(ll)-catalyzed hydration reaction of a terminal alkyne because different products result. Direct hydration with aqueous acid and mercury(IJ) sulfate leads to a methyl ketone, whereas hydroboration/oxidation of the same terminal alkyne leads to an aldehyde. 

The chemistry of alkynes is dominated by electrophilic addition reactions, similar to those of alkenes. Alkynes react with HBr and HC1 to yield vinylic halides and with Br2 and Cl2 to yield 1,2-dihalides (vicinal dihalides). Alkynes can be hydrated by reaction with aqueous sulfuric acid in the presence of mercury(ll) catalyst. The reaction leads to an intermediate enol that immediately isomerizes to yield a ketone tautomer. Since the addition reaction occurs with Markovnikov regiochemistry, a methyl ketone is produced from a terminal alkyne. Alternatively, hydroboration/oxidation of a terminal alkyne yields an aldehyde. 

I Methyl ketones are prepared by hydration of terminal alkvnes in the presence of Hg2+ catalyst (Section 8.4). 

The hydration of triple bonds is generally carried out with mercuric ion salts (often the sulfate or acetate) as catalysts. Mercuric oxide in the presence of an acid is also a common reagent. Since the addition follows Markovnikov s rule, only acetylene gives an aldehyde. All other triple-bond compounds give ketones (for a method of reversing the orientation for terminal alkynes, see 15-16). With allqmes of the form RC=CH methyl ketones are formed almost exclusively, but with RC=CR both possible products are usually obtained. The reaction can be conveniently carried out with a catalyst prepared by impregnating mercuric oxide onto Nafion-H (a superacidic perfluorinated resinsulfonic acid). ... 

On the basis of these results and Damiano s report [28], Darcel et al. described an iron-catalyzed hydration of terminal alkynes using catalytic amounts of iron(III) chloride (10 mol%). The reaction selectively leads to the corresponding methyl ketone derivatives (Scheme 11) [29]. Iron(II) species such as FeCl2 or Fe(OAc)2 were not able to promote the reaction, the starting phenylacetylene remained unchanged after several days at 75°C. 

The above-postulated overall mechanism considers two alternative pathways depending on the nature of the acetylene derivative. Region A outlines a proposal in which the formation of the a-complex intermediate is supported by the fact that the treatment of aliphatic terminal acetylenes with FeCl3 led to 2-chloro-l-alkenes or methyl ketones (Scheme 12). The catalytic cycle outlined in region B invoked the formation of the oxetene. Any attempt to control the final balance of the obtained... 

Hydration of unactivated alkynes is an important method for functionalizing this plentiful hydrocarbon source. Therefore, a variety of metal ions have been proposed as catalysts for this reaction, and almost all of the reported additions of water to terminal alkynes follow the Markonikov rule. The hydration of l-aUcynes with Hg(II) salts in sulfuric acid [85], RuCh/aq.HCl [86, 87], K[Ru (edta-H)Cl] 2H20 [88], RhCl,.3H20/aq. HCl [89], RhCl3/NR4 [90], Zeise-type Pt(II) complexes [91-93], and NaAuCl4 [94] produced exclusively methyl ketones (Eq. 6.46). 

The most synthetically valuable method for converting alkynes to ketones is by mercuric ion-catalyzed hydration. Terminal alkynes give methyl ketones, in accordance with the Markovnikov rule. Internal alkynes give mixtures of ketones unless some structural feature promotes regioselectivity. Reactions with Hg(OAc)2 in other nucleophilic solvents such as acetic acid or methanol proceed to (3-acetoxy- or (3-methoxyalkenylmercury intermediates,152 which can be reduced or solvolyzed to ketones. The regiochemistry is indicative of a mercurinium ion intermediate that is opened by nucleophilic attack at the more positive carbon, that is, the additions follow the Markovnikov rule. Scheme 4.8 gives some examples of alkyne hydration reactions. 

The Wacker reaction can also be applied to laboratory-scale syntheses.104 When the Wacker conditions are applied to terminal alkenes, methyl ketones are formed.105... 

The study of alkynylation of methyl ketones using a terminal alkyne, ZnMe2, and a salen derivative 196 as a chirality inductor provided a new method for the preparation of ct-hydroxyacetylenes (197, Scheme 112).292... 

Queen substance (140) was synthesized from the same telomer 137 (127). The PdCl2-catalyzed oxidation of the terminal double bond produced the methyl ketone. Reduction of the internal double bond was followed by partial hydrolysis and the displacement of the carboxyl group with phenylselenyl group, which was removed to produce queen substance (140) ... 

Nonadienoate was used for the convenient synthesis of 2,15-hexa-decanedione (130) (131). The terminal double bond was oxidized to methyl ketone 147 with PdCl2, and the internal double bond was reduced. Hy-... 

Anodic oxidation is used to promote the recycling of palladium(il) in the Wacker process for the conversion terminal alkenes to methyl ketones. Completion of the catalytic cycle requires the oxidation of palladium(O) back to the palla-dium(li) state and this step can be achieved using an organic mediator such as tri(4-bromophenyljamine. The mediator is oxidised at the anode to a radical-cation and... 

In anhydrous CDjClj, the P-chelate (7) underwent slow degradation with time, yielding predominantly vinyl methyl ketone as termination organic product, together with several palladium species and also Pd metal (Figure 7.14). 

Similar 0—4 generations silica-supported Pd-PAMAM dendrimers with various spacer lengths were used by Alper et al. as recyclable catalysts for the hydroesterification reaction of alkenes (55) and the oxidation of terminal alkenes to methyl ketones (56). The hydroesterification experiments (Scheme 16) showed that (PPh3)2Pd-PPh2-PAMAM-Si02 complexes were highly active catalysts for styrene derivatives and linear long-chain alkenes (numbers of turnovers up to 1200). 

The selective oxidation of terminal aikenes to the corresponding methyl ketones was reported by Roussel and Mimoun in 1980 and can be carried out using f-butylperoxypalladium(II) trifluoroacetate (PPT) or alternatively catalytic amounts of... 

SCHEME 136. Palladium-catalyzed oxidation of terminal olefins to methyl ketones by TBHP or H2O2... 

SCHEME 137. Proposed mechanism for the palladium-catalyzed oxidation of terminal alkenes to methyl ketones using TBHP oxidant... 

An organic/fluorous biphasic approach (CsFnBr/benzene) to the synthesis of methyl ketones from terminal alkenes with TBHP in the presence of catalytic amounts of the palladium catalyst 215 was presented by Betzemeier and Knochel in 1998 (Scheme 139) °. 

With this method styrene derivatives are oxidized in very good yields (complete conversion at 56 °C after 2-5 hours), whereas aliphatic alkenes require longer reaction time (8-20 h) and increased amounts of oxidant (3.5 eq.), and afford methyl ketones in moderate to good yields. Besides terminal olefins also stilbene and ethyl cinnamate have been converted to benzyl phenyl ketone and /3-ketoester. The catalyst solution can be reused 8 times without decrease in yield. 

In 1960, Moiseev and coworkers reported that benzoquinone (BQ) serves as an effective stoichiometric oxidant in the Pd-catalyzed acetoxylation of ethylene (Eq. 2) [19,20]. This result coincided with the independent development of the Wacker process (Eq. 1, Scheme 1) [Ij. Subsequently, BQ was found to be effective in a wide range of Pd-catalyzed oxidation reactions. Eor example, BQ was used to achieve Wacker-type oxidation of terminal alkenes to methyl ketones in aqueous DMF (Eq. 3 [21]), dehydrogenation of cyclohexanone (Eq. 4 [22]), and alcohol oxidation (Eq. 5 [23]). In the final example, 1,4-naphthoquinone (NQ) was used as the stoichiometric oxidant. 

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