α-alchilazione di aldeidi, via organocatalisi: un approccio sintetico e computazionale

During this internship, the α-alkylation of branched aldehydes was taken into consideration. An enantiopure Betti’s base derivative was used as catalyst, applying a new concept in catalysis: organocatalysis. The Betti’s base may be of particular interest for organic chemists working in the field of “reactions catalysed by enantiopure small organic molecules”, in particular for the ones interested in enantiopure primary amines. The potential of secondary amines as catalysts has certainly been known for years. It is indeed more innovative to conduct reactions using primary amine derivatives as catalyst. In this work, the efficacy of the primary amine was checked first. Then, the focus was set on finding optimal reaction conditions. Finally, to have a more complete picture of the structure of the compounds used in the project, experimental and computational IR spectra were compared, after the method was validated. Durante il periodo di tirocinio è stata presa in esame la reazione di α-alchilazione di aldeidi branched, utilizzando un derivato dell’ammina di Betti come catalizzatore enantiopuro ed applicando un nuovo tipo di catalisi: l’organocatalisi. Questi composti possono essere di particolare interesse per lavori in chimica organica, nel campo delle reazioni catalizzate da “piccole” molecole organiche, in particolare da ammine primarie a chiralità definita; la potenzialità delle ammine secondarie chirali come catalizzatori è certamente nota da anni, ma innovativo è condurre il tutto con l’impiego di un derivato amminico primario. Altri aspetti significativi sono gli apparenti e innumerevoli vantaggi, dal punto di vista economico ed ambientale, oltre che operativo e sintetico, derivanti dal nuovo tipo di catalisi. In un primo momento è stata verificata l’efficacia dell’ammina primaria sintetizzata nella reazione in progetto, quindi sono state individuate le condizioni di reazione ottimali. Infine, per un’analisi più completa di alcune molecole organiche e dopo un’opportuna validazione del metodo utilizzato, sono stati ottenuti a livello computazionale gli spettri IR delle molecole di sintesi prodotto e catalizzatore.

Synthesis of enantiopure cyclopentanones by desymmetrization of allylic cyclobutanols

The interest in five-membered ring molecules derives from their important application in many different fields, such as pharmaceutical and agrochemical areas. A common strategy for their formation is four-membered ring expansion, which also allows to add molecular complexity and functional handles within one single operation starting from readily available starting materials. Organocatalysis can be exploited to promote the reaction and to obtain a good enantio- and diastereoselection. This technique involves the exclusive use of organic molecules as catalysts, without resorting to metals. The aim of this work is to obtain enantiopure cyclopentanones starting from achiral allylic cyclobutanols. The reaction consists in a ring expansion promoted by the addition of a halogen to the double bond of the substrate, with formation of a haliranium ion as intermediate, followed by a semipinacol rearrangement to afford the cyclopentanone. The reaction is catalysed by a chiral phosphoric acid that, besides accelerating the rate of the reaction, transmits a specific chirality thanks to its chiral structure, following the asymmetric catalysis principles. Starting from symmetric trans-allylic cyclobutanols, the whole reaction is a desymmetrization and leads to the formation of two new stereogenic centres: a mixture of diastereoisomers is obtained, each as couple of enantiomers; the ratio between the possible configurations is determined by the relative position that the chiral catalyst and the reagent occupy during the reaction. Since the reaction is already optimized, the original aim was to study the scope: first, the synthesis of a set of allylic cyclobutanols and their relative precursors, in order to have a wider range of substrates; then, the identification of the type of substrate that undergoes the expansion, with the study of enantio- and diastereoselectivity obtained in each case. Due to the Covid-19 emergency, most of the work was developed as a bibliographic study.

Computational study on the asymmetric aminocatalysed Michael addition reaction of cyclohexanone to trans–β–nitrostyrene

Asymmetric organocatalysed reactions are one of the most fascinating synthetic strategies which one can adopt in order to induct a desired chirality into a reaction product. From all the possible practical applications of small organic molecules in catalytic reaction, amine–based catalysis has attracted a lot of attention during the past two decades. The high interest in asymmetric aminocatalytic pathways is to account to the huge variety of carbonyl compounds that can be functionalized by many different reactions of their corresponding chiral–enamine or –iminium ion as activated nucleophile and electrophile, respectively. Starting from the employment of L–Proline, many useful substrates have been proposed in order to further enhance the catalytic performances of these reaction in terms of enantiomeric excess values, yield, conversion of the substrate and turnover number. In particular, in the last decade the use of chiral and quasi–enantiomeric primary amine species has got a lot of attention in the field. Contemporaneously, many studies have been carried out in order to highlight the mechanism through which these kinds of substrates induct chirality into the desired products. In this scenario, computational chemistry has played a crucial role due to the possibility of simulating and studying any kind of reaction and the transition state structures involved. In the present work the transition state geometries of primary amine–catalysed Michael addition reaction of cyclohexanone to trans–β–nitrostyrene with different organic acid cocatalysts has been studied through different computational techniques such as density functional theory based quantum mechanics calculation and force–field directed molecular simulations.

Computational characterization of carbazole-benzonitrile derivatives for applications in Organic Light Emitting Diodes

The technology of Organic Light-Emitting Diodes has reached such a high level of reliability that it can be used in various applications. The required light emission efficiency can be achieved by transforming the triplet excitons into singlet states through Reverse InterSystem Crossing (RISC), which is the main process of a general mechanism called thermally activated delayed fluorescence (TADF). In this thesis, we theoretically analyzed two carbazole-benzonitrile (donor-acceptor) derivatives, 2,5-di(9H-carbazol-9-yl)benzonitrile (p-2CzBN) and 2,3,4,5,6-penta(9H-carbazol-9-yl)benzonitrile (5CzBN), and addressed the problem of how donor-acceptor (D-A) or donor-acceptor-donor (D-A-D) flexible molecular architectures influence the nature of the excited states and the emission intensity. Furthermore, we analyzed the RISC rates as a function of the conformation of the carbazole lateral groups, considering the first electronic states, S0, S1, T1 and T2, involved in TADF process. The two prototype molecules, p-2CzBN and 5CzBN, have a similar energy gap between the first singlet and triplet states (∆EST, a key parameter in the RISC rate), but different TADF performances. Therefore, other parameters must be considered to explain their different behavior. The oscillator strength of p-2CzBN, never tested as emitter in OLEDs, is similar to that of 5CzBN, which is an active TADF molecule. We also note that the presence of a second T2 triplet state, lower in energy than S1 only in 5CzBN, and the reorganization energies, associated with RISC processes involving T1 and T2, are important factors in differentiating the rates in p-2CzBN and 5CzBN. For p-2CzBN, the RISC rate from T2 to S1 is surprisingly higher than that from T1 to S1, in disagreement with El-Sayed rules, due to a large reorganization energy associated to the T1 to S1, process; while the contrary occurs for 5CzBN. These insights are important for designing new TADF emitters based on the benzo-carbazole architecture.