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Aldehyde alkylation

The hydroxyl groups on glycols undergo the usual alcohol chemistry giving a wide variety of possible derivatives. Hydroxyls can be converted to aldehydes, alkyl hahdes, amides, amines, a2ides, carboxyUc acids, ethers, mercaptans, nitrate esters, nitriles, nitrite esters, organic esters, peroxides, phosphate esters, and sulfate esters (6,7). [Pg.357]

CHIRAL CATALYST-INDUCED ALDEHYDE ALKYLATION ASYMMETRIC NUCLEOPHILIC ADDITION... [Pg.107]

Chiral Catalyst-Induced Aldehyde Alkylation Asymmetric... [Pg.513]

Scheme 1. Catalytic enantioselective aldehyde alkylation affords the chiral macrocyclic alcohol 3 in Oppolzer s total synthesis of muscone (1993). Scheme 1. Catalytic enantioselective aldehyde alkylation affords the chiral macrocyclic alcohol 3 in Oppolzer s total synthesis of muscone (1993).
The C-H bond in CBnHi2 and related anions can be metallated by butyllithium and then converted into C-substituted anions with aldehydes, alkyl halides, Ph3SiCl, and Ph2PCl.322-329 C-halogenated (F,Cl,Br, or I) derivatives are made from the C-copper derivative with (PhS02)2NF or the corresponding N-halosuccinimide.330 The l-Me-2,3>4,5,6,7,8,9,10,ll>12-Fu-CBii- anion is made from the reaction of the corresponding Fn anion with... [Pg.68]

The definition of what constitutes reactive or unstable functionality naturally varies somewhat, but there is also a good deal of consensus (aldehydes, alkyl halides, vinyl ketones, and so forth) [14,16-18]. [Pg.145]

For example, with the Co-I-PPh catalyst, methyl acetate reacts with synthesis gas to form ethyl acetate. All of the primary and secondary alcohols tested (C thru C ) decompose during long-term operation. The major decomposition products include aldehydes, alkyl iodides, and ethers. Ketones are readily hydrogenated and the resulting alcohols decompose. Good solvents in terms of stability are diphenyl ether and alkanes. The acetaldehyde rate is somewhat low (1.8 M/hr) in diphenyl ether, and the selectivity is low in alkanes. In addition, these solvents do not have good solubility properties, especially in product refining. [Pg.131]

The numerous preparations of mono-, di-, tri-, and hexafluoro derivatives of valine, norvaline, leucine, norleucine, and isoleucine, using classical methods of amino acid chemistry (e.g., amination of an a-bromoacid, " azalactone, Strecker reaction, amidocarbonylation of a trifluoromethyl aldehyde, alkylation of a glycinate anion are not considered here. Pure enantiomers are generally obtained by enzymatic resolution of the racemate, chemical resolution, or asymmetric Strecker reaction. ... [Pg.152]

Upon oxidizing ethene, propene, or isobutene together with aldehydes, alkylated aromatic hydrocarbons, methyl ethyl ketone or other... [Pg.16]

Amino acids may also undergo thermal degradation, which is almost always coupled with some other food components, particular sugars. The major types of volatile compounds formed from amino-sugar interactions include Strecker degradation aldehydes, alkyl pyrazines, alkyl thiazolines and thiazoles and other heterocycles [35, 36]. As the subject has mainly relevance for baked and roasted vegetable food products, this subject will not be discussed in further detail. [Pg.140]

Aldehydes Alkyl halides Calcium sulphate, magnesium sulphate, sodium sulphate. Calcium chloride, calcium sulphate, magnesium sulphate, phosphorus pentoxide, sodium sulphate. [Pg.38]

To capture electrophilic substrates such as acid halides, aldehydes, alkyl halides, isocyanates, and isothiocyanates, a variety of nucleophilic resins are commonly used. Some commercially available and representative examples are tris-(2-aminoethyl)amine (9), thiophenol (10), sulfonylhydrazide (11), triphenylphosphine (12), and methylthiourea (13) polymer resins (Fig. 6). [Pg.397]

Due to the increased reactivity of the aldehyde, alkyl-substituted nitroolefins can also be used as substrates. Nevertheless, these reactions are usually low-yielding and afford moderate selectivity. Alexakis has shown, however, that the bispyrrolidine 5-catalyzed additions may be used in multistep synthesis. The addition of propionaldehyde 34 to nitroolefin 33 resulted an approximate 2 3 mixture of anti/syn isomers in 92% yield and in high ee (93%), allowing the asymmetric synthesis of (—)-botryodiplodin (Scheme 2.46) [23b]. [Pg.86]

Fig. 30 Asymmetric aldehyde alkylation using organocatalyst 119 and reductive photoredox catalysis... Fig. 30 Asymmetric aldehyde alkylation using organocatalyst 119 and reductive photoredox catalysis...
Hydrides from carboxylic acids Carboxylic acids from hydrides Carboxylic acids from hydrides Esters from hydrides Hydrides from aldehydes Hydrides from aldehydes Alkyls from aldehydes Ketones from methylenes Ketones from ketones Alkyls from olefins Acetylenes from halides also acetylenes from acetylenes Esters from alcohols also esters from carboxylic acids Alkyls from olefins Alkyls from olefins... [Pg.7]

Predict the products of reactions of amines with ketones and aldehydes, alkyl halides and tosylates, acid chlorides, sulfonyl chlorides, nitrous acid, and oxidizing agents. Propose mechanisms where appropriate. [Pg.928]

That said, enamines are a good solution to the aldehyde enolate problem. Aldehydes form enamines very easily (one of the advantages of the electrophilic aldehyde) and these are immune to attack by nucleophiles—including most importantly the enamines themselves. Below are two examples of aldehyde alkylation using the enamine method. [Pg.673]

Additions to Aldehydes. Alkylation of aromatic and aliphatic aldehydes with a combination of titanium tetraisopropoxide, Ti(0-/-Pr)4, and diethy Izinc, ZnEt2, in the presence of a catalytic amount of the bis-sulfonamide la leads to formation of (S)-l-phenyl-1-propanol 4 with high enantioselectivity (eq 2, Table 1). Use of the (R,7 )-l,2-(trifluoromethanesulfonamido)-cyclohexane lb [CAS 122833-60-7] allows for an equally selective reaction, but at exceptionally low catalyst loadings. In the case of aromatic aldehydes, these reactions are fairly rapid, requiring at most 2 hours to reach full conversion. [Pg.395]

Early work by Papa et al. indicated that reduction of carbonyl compounds with Raney nickel in alkaline solution gave the corresponding hydrocarbon or alcohol products, and formation of the hydrocarbon was only feasible in the case of aromatic carbonyl compounds at 80-90 C. Mitchell et al. reported an improved method under neutral conditions using W-7 Raney nickel in 50% aqueous ethanol, aryl aldehydes, alkyl aryl and diaryl ketones can be reduced to the methylene products in high yields. Aromatic substituents such as nitro, cyano and halogen also suffer reduction under these conditions. [Pg.320]

See other pages where Aldehyde alkylation is mentioned: [Pg.1139]    [Pg.506]    [Pg.163]    [Pg.43]    [Pg.620]    [Pg.37]    [Pg.47]    [Pg.172]    [Pg.1139]    [Pg.111]    [Pg.54]    [Pg.108]    [Pg.1139]    [Pg.72]    [Pg.461]    [Pg.136]    [Pg.676]    [Pg.113]    [Pg.59]    [Pg.296]    [Pg.1135]   
See also in sourсe #XX -- [ Pg.370 ]

See also in sourсe #XX -- [ Pg.95 ]

See also in sourсe #XX -- [ Pg.370 ]



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Aldehydes 2-alkyl-4-amino-5-aryloxazoles

Aldehydes Friedel-Crafts alkylation

Aldehydes Friedel-Crafts alkylations

Aldehydes a-alkylated

Aldehydes a-alkylation

Aldehydes alkyl enol ether derivatives

Aldehydes alkyl halides

Aldehydes alkyl vinyl ketones

Aldehydes alkylation with alcohols

Aldehydes alkylation, Cope rearrangement

Aldehydes alkylations

Aldehydes continued alkylation reactions

Aldehydes dienolates, alkylation

Aldehydes enantioselective alkylation with

Aldehydes enolates, alkylation

Aldehydes from alkyl halides

Aldehydes sulfoxides + alkyl halides

Aldehydes with metal alkyls

Aldehydes zinc alkyl addition

Aldehydes, alkylation autocatalysis

Aldehydes, alkylation phenylation

Aldehydes, alkylation transfer hydrogenation

Aldehydes, aromatic, synthesis from alkyl halides

Aldehydes, asymmetric alkylation

Aldehydes, asymmetric alkylation dialkylzinc reagents

Aldehydes, reductive alkylation

Aldehydes, reductive alkylation alkenes, reagents

Aldehydes, reductive alkylation reagents

Aldehydes, reductive alkylation tautomerism

Aldehydes, reductive alkylation vinylation

Aldehydes, reductive alkylation with alcohols

Alkyl groups in aldehydes and ketones

Alkyl to aldehydes

Alkyl vinyl ketones, Michael reactions, aldehydes

Alkyl/aryl/heteroaryl aldehydes

Alkylation by aldehydes

Alkylation of Aldehydes, Esters, Amides, and Nitriles

Alkylation of Aldehydes, Esters, Carboxylic Acids, Amides, and Nitriles

Alkylation of aldehydes

Alkylation of aldehydes and ketones

Alkylation, aromatic aldehyde

Alkylative amination aldehydes

Alkyls => aldehydes

Amination alkylation of aldehydes

Asymmetric a-alkylation aldehydes and ketones

Asymmetric alkylation of aldehydes

Boranes, alkyl reaction with aldehydes

Bromides, acyl, from aldehydes halides, alkyl

Dialkylzinc aldehyde alkylation

Dithioacetals, alkylation from aldehydes

Hydroxy aldehydes, alkylation

Hydroxy aldehydes, alkylation oxidation

Ketone Alkylation with aldehyde

Ketone-aldehydes => alkyl halides

Ketones and aldehydes, distinguishing from alkylation

O-alkyl aromatic aldehyde

P-Keto aldehydes alkylation

Reaction XIV.—(a) Action of Magnesium Alkyl or Aryl Halide on Aldehydes and Ketones (Grignard)

Reductive alkylation of aldehydes and ketones

Silane, a-phenylthiomethyltrimethylreaction with alkyl halides synthesis of aldehydes

Using specific enol equivalents to alkylate aldehydes and ketones

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