Rate acceleration rearrangement

Dramatic rate accelerations of [4 + 2]cycloadditions were observed in an inert, extremely polar solvent, namely in5 M solutions oflithium perchlorate in diethyl ether(s 532 g LiC104 per litre ). Diels-Alder additions requiring several days, 10—20 kbar of pressure, and/ or elevated temperatures in apolar solvents are achieved in high yields in some hours at ambient pressure and temperature in this solvent (P.A. Grieco, 1990). Also several other reactions, e.g, allylic rearrangements and Michael additions, can be drastically accelerated by this magic solvent. The diastereoselectivities of the reactions in apolar solvents and in LiClO EtjO are often different or even complementary and become thus steerable. 

For a number of years, a storm of controversy raged over this proposal, with H. C. Brown as the chief opponent. Brown ruled out anchimeric assistance as an explanation for the rate acceleration of the exo derivative, arguing that exo was normal, but that endo was unusually slow because of a steric effect. The racemization and isotopic tracer results, he proposed, could be explained by a rapid equilibrium between the classical ions 15 and 17 (see Scheme 1.3), with a steric effect responsible for the exo addition of nucleophiles. In terms of the cation, the question revolves around the issue whether the classical ions 15 and 17 should be joined by the equilibrium depiction (the rapidly rearranging scenario) or with a... 

Cope rearrangement of arylazo-t-allylmalononitriles [236] shows rate acceleration by acceptor substituents in the phenyl ring. Again, a more polar transition state favor the reorganization. 

The cyclopropylmethyl ion 11 is unusually stable and has a 14kcal/mol barrier to rotation about the cyclopropyl-carbocation bond.69 In contrast, the corresponding cyclobutylmcthyl ion 12 quickly rearranges to a cyclopentyl cation. Here, some strain relief occurs in the rearrangement, but this is opposed by the conversion of the stable tertiary carbocation to the less stable secondary ion. Although rearrangement is the normal process for cyclobutylmethyl cations, there is one case 13 in which rearrangement does not occur, and a small rate acceleration is observed.70... 

Upon binding the rates of rearrangement are accelerated for all substrates studied. The measured activation parameters of the reactions reveal that the supramolecular host can reduce both the entropic and the enthalpic barriers for the rearrangement. The capsule acts as a true catalyst, since release and hydrolysis facilitates turnover. 

Analysis of the activation parameters for the different encapsulated substrates reveals that the source of catalysis is more complex than simply a reduction of the entropy of activation, since different effects are observed for substrates 26,27,30. While the rate acceleration for the encapsulated 26 was exclusively due to lowering the entropic barrier, for 27 and 30 a decrease in the enthalpic barrier for rearrangement is observed in addition. It is possible that, for 27 and 30 binding into the narrow confines of the metal-ligand assembly induces some strain on the bound molecules, thereby raising their ground-state energies compared to those of the unbound... 

This reaction rearranges the carbonyl and hydroxyl groups on carbons 1 and 2. However, more than 80% of the enzymatic rate acceleration has been traced to enzyme-substrate interactions involving the phosphate group on carbon 3 of the substrate. This was determined by a careful comparison of the enzyme-catalyzed reactions with glyceraldehyde 3-phosphate and with glyceraldehyde (no phosphate group at position 3) as substrate. 

The use of 3- or 4-picolylamine instead of benzylaminc with ethyl 4,4.4-trifluoro-3-oxobutanoate results in the expected (vide supra) rate acceleration in the isomerization of the corresponding enamines, analogs of 29a.15 Thus, ethyl 4,4,4-trifluoro-3-[(3-pyridylmethyl)-amino]but-2-enoate undergoes the enamine-azomethine-azomethine isomerization at room temperature in 36 hours to give the /J-(3-pyridylmethyleneamino) ester in 91 % yield. In the case of the 4-picolylamine derivative, complete isomerization occurs in 4 hours at room temperature to give the desired rearranged product in 86% yield.15... 

A kinetic study of the Cope rearrangement of 2-(trifluoromethyl)oeta-l.5-diene [(Z)-7] showed no rate acceleration in comparison with the rearrangement of unsubsliluled hexa-1,5-diene. Equilibrium was reached after 7 days at 207 C (K = 3.46 favoring the is-isomer). at which stage no intermediate 4-ethylhcxa-l,5-diene 8 was observed.6 In contrast, a trifluoromethyl group at position 2 does accelerate the Claisen rearrangement (sec Section 5.1.5.2.). 

A second general approach to allyl /(-lluorovinyl ether intermediates involves the reaction of a /J-fluoro alcoholate with an allylic halide. Claisen rearrangement then produces a-fluoro carbonyl compounds. Although the tremendous rate acceleration caused by a-fluoro substitution in the vinyl fragment is not present here, the rearrangements take place under synthetically useful conditions. 

Acceleration of Claisen rearrangements.2 The Claisen rearrangement of an allyl vinyl ether is markedly accelerated by a stabilized a-sulfonyl carbanion at the 2-position. Thus 1 and 2 rearrange to the y,d-unsaturated ketone 3 in the presence of potassium hydride and 18-crown-6 at moderate temperatures. Rates can be further enhanced by addition of HMPT. Substitution of methyl groups on either the allyl or vinyl units does not affect the regioselectivity but can accelerate the rate of rearrangement. 

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