Claisen aliphatic

Claisen-Schmidt reaction. Aromatic aldehydes condense with aliphatic or mixed alkyl-aryl ketones in the presence of aqueous alkali to form ap-unsaturated ketones ... 

The Claisen condensation of an aliphatic ester and a thiazolic ester gives after acidic hydrolysis a thiazolylketone (56). For example, the Claisen condensation of ethyl 4-methyl-5-thiazolecarboxylate with ethyl acetate followed by acid hydrolysis gives methyl 4-methyl-5-thiazolyl ketone in 16% yield. 

Claisen reaction is the condensation of benzaldehyde with aliphatic aldehydes and ketones containing a-hydrogen C6H5CHO -r CH3CHO C6H5CH=CH CHO -r HjO... 

Crossed aldol condensations, where both aldehydes (or other suitable carbonyl compounds) have a-H atoms, are not normally of any preparative value as a mixture of four different products can result. Crossed aldol reactions can be of synthetic utility, where one aldehyde has no a-H, however, and can thus act only as a carbanion acceptor. An example is the Claisen-Schmidt condensation of aromatic aldehydes (98) with simple aliphatic aldehydes or (usually methyl) ketones in the presence of 10% aqueous KOH (dehydration always takes place subsequent to the initial carbanion addition under these conditions) ... 

There is no unity of opinion in the literature concerning a classification, i.e, whether to call these transformations aza-Claisen or aza-Cope rearrangements. It is accepted that the term aza-Claisen should be reserved only for those processes in which a carbon atom in the allyl vinyl ether system has been replaced by nitrogen357. Three different types of aliphatic 3-aza-Cope reactions which were studied theoretically are the rearrangements of 3-aza-l,5-hexadienes (610, equation 262), 3-azonia-l,5-hexadienes (611, equation 263) and 3-aza-l,2,5-hexatrienes (612, equation 264) (the latter is a ketenimine rearrangement )357. 

Claisen-Schmidt condensation org chem A reaction employed for preparation of unsaturated aldehydes and ketones by condensation of aromatic aldehydes with aliphatic aldehydes or ketones in the presence of sodium hydroxide. klas-on jshmit kand-on sa-shon ... 

Secondary aliphatic amines were found to give higher yields of thienothiophenes than did tertiary amines, which are weaker bases. A maximum ratio of thienothiophenes to thienothiopyrans of about 4 1 was achieved at 145° with diisopropylamine as cat yst and DMSO as solvent. Only thienothiopyrans were formed in DMF in the presence of the same catalyst The amines promote nucleophilic cyclization of Claisen rearrangement products into thienothiophenes. Since thienothiophenes are resistant to treatment with potassium t-butoxide in DMSO and thienothiopyrans form resinous products under these conditions, the method is a convenient route to pure thienothiophenes 35 and 42 in yields of up to 40%. ... 

The ruthenium-catalyzed direct addition of saturated aliphatic alcohols to non-activated alkynes remains a challenge. Only ally alcohol has been successfully involved in the intermolecular addition to phenylacetylene to produce an ether and the enal resulting from Claisen rearrangement (Equation 10.7) [24]. Thus, in refluxing toluene, in the presence of a catalytic amount of RuCl(tris(pyrazolyl) borate) (pyridine)2, a 1 1 mixture of ally P-styryl ether and 2-phenylpent-4-enal was obtained in 72% overall yield. 

In this section, the aliphatic Cope and Claisen rearrangements, as depicted in the transformation of I to 2 in Scheme 2, are discussed, as well as variations of the latter (i.e.. Johnson-Claisen, Ireland-Claisen, Reformatsky Claisen, F.schenmoser-Claisen. Ficini Claisen, and hetero-Claisen rearrangements). When X is oxygen, replacement of Cl and C2 with an aromatic ring... 

Aliphatic Claisen Rearrangements Fluorine Substitution on the Vinyl Fragment... 

This method offers an alternative to the reaction of allylic alcohols with tetrafluoroethene to form acids 3 via an aliphatic Claisen rearrangement (see Section 5.1.5.2.). The reaction of la is four times as fast as that of allyl trjchloroacetate under similar conditions. In the absence of chlorotrimethylsilane, no rearrangement occurs. 

Reaction XXVI. (a) Condensing Action of Potassium Cyanide, Potassium Carbonate, or other substances on Aliphatic (Claisen) and Aromatic Aldehydes (Liebig). (J. C. S., 117, 324.)—With aliphatic and aromatic aldehydes this condensation follows very different lines. In the former the condensation takes place between the aldehydic carbon of one molecule and the a-carbon of another molecule. The same or different aldehydes may be used. 

A retrosynthetic analysis of a,/J-unsaturated ketones leading to various methods of synthesis is outlined in Section 5.18.2, p. 798. These methods are equally applicable to aromatic aldehydes. Aromatic aldehydes condense with aliphatic or mixed alkyl aryl ketones in the presence of aqueous alkali to form a,[i-unsaturated ketones (the Claisen-Schmidt reaction). 

Aliphatic Claisen rearrangement,4 Allyl vinyl ethers undergo [3, 3] sigmatropic rearrangement in the presence of (CH3)3A1 or (C2H5)3A1 with substitution of CH3 or C2H5 on the aldehydic carbon atom (equation I). 

The aliphatic Claisen Rearrangement is a [3,3]-sigmatropic rearrangement in which an allyl vinyl ether is converted thermally to an unsaturated carbonyl compound. 

We used the all-carbon Cope rearrangement 29 to introduce this section but now we want to feature the more useful Claisen rearrangements.14 The aliphatic Claisen 54 works for most substituents because an alkene is lost and a much more stable carbonyl group is formed 55. It doesn t matter whether we have an aldehyde (X = H), a ketone, (X = R), an acid (X — OH), an ester (X = OR) or an amide (X = NR2), the reaction works well. The original Claisen rearrangement was the aromatic version 56 that gives an unstable non-aromatic intermediate 57 that quickly loses a proton to restore the aromatic ring and the product is a phenol 58. 

The aliphatic Claisen rearrangement is simpler in that there is no rearomatisation at the end but there is an ionic step first as the vinyl ether 67 has to be made and the easiest way to do that is from the allylic alcohol 65 by acetal exchange with another vinyl ether to give 66 and elimination to give 67. All these steps, including the rearrangement occur under the same conditions16 and the product is a y,S-unsaturated carbonyl compound 68. 

In the last chapter we used 79 in an aliphatic Claisen rearrangement to make an anisatin intermediate. You can now see that 79 was made by Birch reduction of 80. With a Friedel-Crafts in mind, we change the alcohol for a ketone 81 and start with 82. 

The presence of jr-electron-donating substituents at the 2-position of the vinyl portion of the ether allows for significant acceleration of the Claisen rearrangement.314-318 Aliphatic Claisen rearrangements can proceed in the presence of organoaluminum compounds,286-319-320 although other Lewis acids have failed to show reactivity.286,321 324 Useful levels of (Z)-stereoselection and asymmetric induction have been obtained by use of bulky chiral organoaluminum Lewis acids.325 327... 

The experimental KIEs were determined for the aliphatic Claisen rearrangement in p-cymene at 120°C and for the aromatic Claisen rearrangement either neat at 170°C or in diphenyl ether at 220°C. Changes in 2H, 13C or 170 composition were determined for unreacted substrates. For carbon analysis of allyl vinyl ether the C5 carbon was used as an internal standard. The C4 atom and rneta aryl protons were used as references in analysis of allyl phenyl ether. The 170 analysis was based on a new methodology. The results are summarized in Table 1, along with predicted isotope effects calculated for experimental temperatures by means of different computational methods. The absolute values of predicted isotope effects for C4 and C5 atoms varied with theoretical level and all isotope effects were rescaled to get reference effects equal to 1.000. 

Taking into consideration the agreement between experimental and predicted isotope effects, in the case of the aliphatic Claisen the best transition state is represented by the MP4/6-31G structure. For both aliphatic and aromatic rearrangements the transition states are intermediate between the B3LYP/6-31G and the MP2/6-31G structures. This publication is a valuable guide in application of KIEs in mechanistic studies. 

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