Mechanistic Investigation into the Sommelet-Hauser Rearrangement of an Allyl Ammonium Ylide Through Determination of 13C KIEs

Collins, Sean Christopher

2010 August 1900

The [2,3]-sigmatropic rearrangement is a pericyclic reaction of great synthetic utility to organic chemists. Within the scope of this reaction exist some cases in which the product corresponding to a [1,2] rearrangement is formed, despite the fact this is a forbidden process. Generally this is explained by a radical dissociation-recombination pathway; however, studies into the failure of transition state theory and the necessity to incorporate dynamic effects into mechanistic theory lead us to believe such products may arise from these phenomena. In particular, the possibility that many of these products result from an “unsymmetrical bifurcating surface” in the potential energy landscape is intriguing. To investigate this possibility, the Sommelet-Hauser rearrangement of N-allyl-N,N-dimethylglycine methyl ester was explored. The combined use of experimental and theoretically predicted kinetic isotope effects (KIEs) has been previously shown to deliver great mechanistic insight into reactions. The combination of these techniques, however, has found little employ in studying [2,3] rearrangements. This combination was used to study this reaction, using the Singleton method for determining small heavy-atom isotope effects. Resulting experimental KIEs suggest the reaction proceeds by an asynchronous, concerted, early transition state, and is relatively exothermic. This agrees with previous studies and Hammond’s postulate. Predicted theoretical KIEs are in good agreement with experimental KIEs, and the associated transition structure confirms the results suggested by experiment. Interestingly, as calculations proceed from gas phase to solvent models, the activation barrier of the reaction increases, while its exothermicity decreases. The energy difference determined between the lowest and second lowest energy transition structures decreases to 0.81 kcal/mol in the PCM model, so we cannot exclude the contribution of this transition structure to the reaction. However, qualitative results from the associated KIEs and energetics are consistent with the lowest energy transition structure. This reaction does not seem to afford the [1,2] product, and most likely dynamic effects are insignificant in determining product distribution. However, the study has validated, with respect to this body of reactions, both the use of the Singleton method for KIE determination and the combination of these experimental and theoretical techniques.

Kinetic Isotope Effects

KIEs

Mechanistic

Physical Organic

[2,3]-Sigmatropic Rearrangement

Sommelet-Hauser

Ammonium Ylide

Dynamic Effects

DFT

Theoretical Calculations

On the mechanisms of sulfur isotope fractionation during microbial sulfate reduction

Leavitt, William Davie

04 June 2015

Underlying all applications of sulfur isotope analyses is our understanding of isotope systematics. This dissertation tests some fundamental assumptions and assertions, drawn from equilibrium theory and a diverse body of empirical work on biochemical kinetics, as applied to the multiple sulfur isotope systematics of microbial sulfate reduction. I take a reductionist approach, both in the questions addressed and experimental approaches employed. This allows for a mechanistic, physically consistent interpretation of geological and biological sulfur isotope records. The goal of my work here is to allow interpreters a more biologically, chemically and physically parsimonious framework to decipher the signals coded in modern and ancient sulfur isotope records. / Earth and Planetary Sciences

Geochemistry

Geobiology

Microbiology

enzyme isotope fractionation

geomicrobial kinetic isotope effects

microbial sulfate reduction

multiple sulfur isotopes

Phanerozoic oxygen

sulfur cycle

Isotopes as Mechanism Spies : Nucleophilic Bimolecular Substitution and Monoamine Oxidase B Catalysed Amine Oxidation Probed with Heavy Atom Kinetic Isotope Effects

MacMillar, Susanna

January 2006

<p>This thesis concerns the study of reaction mechanisms by means of kinetic isotope effects (KIEs). Studies of the nucleophilic bimolecular substitution (S_N2) reaction had the dual purpose of improving our fundamental understanding of molecular reactivity and assessing the ability of kinetic isotope effects to serve as mechanistic tools. The transition state of the S_N2 reaction between a cyanide ion and ethyl chloride in tetrahydrofuran was found to be reactant like and only slightly tighter than has been found previously for the same reaction in dimethyl sulphoxide. One conclusion was that the transition-state structure in this reaction was predicted fairly well by the theoretical calculations, even without solvent modelling. The S_N2 reactions between cyanide ions and <i>para</i>-substituted benzyl chlorides were found to have reactant-like transition states, of which the C_α-Cl bond was most influenced by the <i>para</i>-substitution. Theoretical calculations indicated that the chlorine KIEs could be used as probes of the substituent effect on the C_α-Cl bond if bond fission was not too advanced in the transition state. Furthermore, the nucleophile carbon ¹¹C/¹⁴C KIEs were determined for the reactions between cyanide ions and various ethyl substrates in dimethyl sulphoxide.</p><p>Precision conductometry was employed to estimate the aggregation status of tetrabutylammonium cyanide in tetrahydrofuran and in dimethyl sulphoxide, which is of interest as tetrabutylammonium cyanide is frequently used as the nucleophilic reagent in mechanistic investigations and synthetic reactions. The tendency for ion-pair formation was found to be very slight, significant, and very strong in dimethyl sulphoxide, water, and tetrahydrofuran, respectively. </p><p>The nitrogen kinetic isotope effect on monoamine oxidase B catalysed deamination of benzylamine was determined in an attempt to obtain conclusive evidence regarding the mechanism of the oxidation. Monoamine oxidase is an important drug target in connection with the treatment of, for example, depression and Parkinson’s disease, and knowledge on how the enzyme effects catalysis would facilitate the design of highly selective and efficient inhibitors.</p>

Organic chemistry

kinetic isotope effects

precision conductometry

monoamine oxidase B/MAO B

reaction mechanism

carbon 11C/14C kinetic isotope effect

ion pairing/triple-ion formation

para-substituted benzyl chlorides

tetrabytylammonium cyanide

Organisk kemi

Isotopes as Mechanism Spies : Nucleophilic Bimolecular Substitution and Monoamine Oxidase B Catalysed Amine Oxidation Probed with Heavy Atom Kinetic Isotope Effects

MacMillar, Susanna

January 2006

This thesis concerns the study of reaction mechanisms by means of kinetic isotope effects (KIEs). Studies of the nucleophilic bimolecular substitution (SN2) reaction had the dual purpose of improving our fundamental understanding of molecular reactivity and assessing the ability of kinetic isotope effects to serve as mechanistic tools. The transition state of the SN2 reaction between a cyanide ion and ethyl chloride in tetrahydrofuran was found to be reactant like and only slightly tighter than has been found previously for the same reaction in dimethyl sulphoxide. One conclusion was that the transition-state structure in this reaction was predicted fairly well by the theoretical calculations, even without solvent modelling. The SN2 reactions between cyanide ions and para-substituted benzyl chlorides were found to have reactant-like transition states, of which the Cα-Cl bond was most influenced by the para-substitution. Theoretical calculations indicated that the chlorine KIEs could be used as probes of the substituent effect on the Cα-Cl bond if bond fission was not too advanced in the transition state. Furthermore, the nucleophile carbon 11C/14C KIEs were determined for the reactions between cyanide ions and various ethyl substrates in dimethyl sulphoxide. Precision conductometry was employed to estimate the aggregation status of tetrabutylammonium cyanide in tetrahydrofuran and in dimethyl sulphoxide, which is of interest as tetrabutylammonium cyanide is frequently used as the nucleophilic reagent in mechanistic investigations and synthetic reactions. The tendency for ion-pair formation was found to be very slight, significant, and very strong in dimethyl sulphoxide, water, and tetrahydrofuran, respectively. The nitrogen kinetic isotope effect on monoamine oxidase B catalysed deamination of benzylamine was determined in an attempt to obtain conclusive evidence regarding the mechanism of the oxidation. Monoamine oxidase is an important drug target in connection with the treatment of, for example, depression and Parkinson’s disease, and knowledge on how the enzyme effects catalysis would facilitate the design of highly selective and efficient inhibitors.

Organic chemistry

kinetic isotope effects

precision conductometry

monoamine oxidase B/MAO B

reaction mechanism

carbon 11C/14C kinetic isotope effect

ion pairing/triple-ion formation

para-substituted benzyl chlorides

tetrabytylammonium cyanide

Organisk kemi

Metal catalysed alkylation of carbonyl compounds with formaldehyde

Lorusso, Patrizia

January 2015

Formaldehyde is a chemical used widely in the manufacture of building materials. A remarkable example is represented by the Lucite two-step Alpha technology for the large scale production of methyl methacrylate (MMA), the essential building block of all acrylic-based products. Esters and ketones are important intermediates in the manufacture of acrylate esters therefore α-hydroxymethylenation of carbonyl compounds using formaldehyde as a one carbon alkylating agent and subsequent dehydration to the corresponding methylenated derivatives has been explored in the current work. We report a novel catalytic approach for the synthesis of methyl methacrylate (MMA) via one-pot α-methylenation of methyl propanoate (a chemical intermediate of the ALPHA process) with formaldehyde, generated in situ by Ru-catalysed dehydrogenation of methanol. Elucidation of the mechanism involved in the catalytic dehydrogenation of methanol along with the collateral alcohol decarbonylation reaction was gained through a combined experimental and DFT study. The development of an alternative process where anhydrous formaldehyde is produced in situ would provide a simplification over the current second step of the ALPHA technology where the formaldehyde is initially produced as formalin, subsequently dehydrated to afford anhydrous formaldehyde in order to ensure high selectivity to MMA. As an alternative approach, ketones, in particular 3-pentanone and 2-butanone, were targeted as potential substrates in order to overcome some of the problems related to competing reactions that occur at the ester group. Hydroxymethylenation, followed by dehydration and Baeyer-Villager oxidation, possibly catalysed by enzymes to reverse the normal selectivity, leads to the formation of acrylate esters. The catalytic reaction is enabled by a gold carbene hydroxide complex in such a way that the substrate undergoes C-H activation and the nascent metal alkyl acts as a nucleophile towards the electrophilic formaldehyde, supplied in the form of alcoform* (solution of paraformaldehyde in methanol).

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