Synthetic chemistry with nitrous oxide and triazenes

Nitrous oxide (N2O) has gained much interest because of its physiological effects ("laughing gas") and its negative environmental impact ("greenhouse gas", "ozone-depleting substance"): It has a lifetime of more than 100 years in the atmosphere. Its persistent character shows how challenging it is to convert N2O into more valuable products. From a synthetic point of view, N2O has potential as diazo (N2) transfer reagent, but applications in synthetic organic chemistry are scarce. The main challenges are to capture N2O, avoid the loss of N2, and to overcome poor-selectivity and -yields. Herein, we describe two examples of the incorporation of two nitrogen atoms into the final product. Firstly, we use N2O as diazo transfer reagent in the preparation of triazolopyridines, which are valuable starting materials for heterocyclic compounds. The reactions can be performed under mild conditions and give synthetically interesting triazoles in moderate to good yields. Secondly, general methods to N1 acylated triazenes were missing previously. We developed routes to 1-acyl triazenes via acid-catalyzed hydration, or by gold- or iodine-catalyzed oxidation of 1-alkynyl triazenes. The latter compounds are prepared from N2O. The properties of the N1 acylated triazenes are distinct compared to other triazenes, displaying different physical and chemical properties. Under strong acidic conditions, 1-acyl triazenes act as acylation reagents. Finally, despite that triazene chemistry is known for more than 160 years, the preferred coordination site of acids still remained a matter of debate (N1, N2, or N3). In search of experimental evidence, we have analyzed triflic acid, B(C6F5)3, and PdCl2 adducts of triazenes by IR, NMR spectroscopy and single crystal X-ray crystallography. For all cases, we found the acid coordinating to the N1 atom of the triazene. This preference should be taken into account for future acid- and transition metal-catalyzed reactions with triazenes. Altogether, this thesis contributes to triazene chemistry and synthetic chemistry with N2O. In this way, we provide further evidence that N2O can be used as a diazo donor to get to synthetically interesting N-containing products.

Ring-Opening Reactions of Aminocyclopropanes and Aminocyclobutanes

Mingming Wang

Nitrogen-containing compounds are an important class of molecules in medicinal chemistry, chemical biology, biochemistry, material sciences or environmental sciences. Organic nitrogen occurs in many forms, ranging from small building blocks such as urea, amino acids, nucleotides, to complex natural products, drug molecules, proteins, nucleic acids, among others. The transformation of easily-accessed nitrogen-containing building blocks into more complex nitrogen-containing structures is therefore important for the synthesis of bioactive compounds or functional materials. Interested in donor-acceptor aminocyclopropanes and aminocyclobutanes, we first developed a Lewis-acid catalyzed formal [4+1] cycloaddition of donor-acceptor aminocyclobutanes with isocyanides, which resulted in the formation of cyclopentene-1,2-diamines. We then attempted to develop a formal [3+2] cycloaddition of donor-acceptor aminocyclopropanes with electron-deficient alkenes, which was mechanistically inspired by the Morita-Baylis-Hillman reaction. Apart from the donor-acceptor system, we were also attracted by simple aminocyclopropanes without electron-withdrawing group at vicinal position. We anticipated that the incorporation of cyclopropylamine into carboxylic-containing compounds followed by ring opening functionalization reactions could be used for the synthesis of more complex products. Therefore, we first disclosed an oxidative ring-opening strategy to transform acyl, sulfonyl or carbamate protected aminocyclopropanes into 1,3-dielectrophilic carbon intermediates bearing a halide atom (Br, I) and a N,O-acetal. Replacing the alkoxy group of the N,O-acetal was achieved under acidic conditions via an elimination-addition pathway, while substitution of the halides by nucleophiles was done under basic conditions via a SN2 pathway, generating a wide range of 1,3-difunctionalized propylamines. Based on the transformation described above, we further discovered an efficient synthesis of 4-amino thiochromans starting from simple aminocyclopropanes and thiophenols through a formal [3+3] annulation reaction. Next, we developed an oxidative ring-opening strategy to transform cyclopropylamides and cyclobutylamides into fluorinated imines. The imines can be isolated in their more stable hemiaminal form, with the fluorine atom installed selectively at the terminal position. Both cheap benzophenone with UV A light or organic and inorganic dyes with blue light could be used as photoredox catalysts to promote this process. Various fluorinated amines were then obtained by nucleophilic attack on the hemiaminals in one pot, giving access to a broad range of useful building blocks for medicinal chemistry. Finally, we turned our attention to the synthesis of diamines, which are essential building blocks for the synthesis of agrochemicals, drugs and organic materials, yet their synthesis remains challenging, as both nitrogen moieties need to be differentiated and diverse substitution patterns (1,2-, 1,3 or 1,4) are required. We described a new strategy giving access to 1,2-, 1,3- and 1,4- amido azides as orthogonally protected diamines based on the nitrogen-directed diazidation of alkenes, cyclopropanes and cyclobutanes.Other unsuccessful efforts over the last four years have also been described, together with some preliminary results of ring-opening cyanation and arylation reactions.

EPFL2022

Bronsted and Lewis acid adducts of triazenes

Frederick Mark Chadwick, Farzaneh Fadaei Tirani, Iris Roswitha Landman, Rosario Scopelliti, Kay Severin, Abdusalom Suleymanov

The synthetic utility of triazenes rests on the fact that the triazene function can be cleaved by BrOnsted or Lewis acids, liberating diazonium compounds. However, the preferred coordination site of the acid is still a matter of debate. We have analyzed triflic acid, B(C6F5)(3), and PdCl2 adducts of triazenes by NMR spectroscopy and single crystal X-ray crystallography. In all cases, we observe coordination of the acid to the N1 atom of the triazene. This finding is not only of relevance for acid-induced cleavage reactions, but also for metal-catalyzed reactions with triazenes, which are increasingly being used in synthetic organic chemistry.

2020

Investigations of Diels-Alder reactions in ionic liquids

Ana Vidis

Room temperature ionic liquids comprise an unique class of solvent composed of organic and inorganic-based ions that are molten under ambient conditions. They are characterised by high solvent polarity and low vapour pressure, and can be tailored to have specific physical and chemical properties. Consequently, there has been great interest in exploiting these attributes to accelerate and control organic reactions. One such reaction, the Diels-Alder reaction, is an important [4+2] cycloaddition reaction used extensively in the preparation of cyclic and heterocyclic compounds. Understanding the factors involved in the enhancing this reaction in ionic liquids remains a subject of intense interest and the centrepiece of the dissertation. The objective of the research is to explore the Diels-Alder cycloaddition reaction in ionic liquids, with a view of developing high effective reactions systems, that operate under mild reaction conditions. The role that ionic liquid media plays in facilitating the Diels-Alder reaction is discussed. A range of physical and chemical modes of activating the reaction are discussed including pressure, the application of Lewis acid catalysts, microwave irradiation and ultrasound sonication and a comparison on the various modes of activation is provided. Importantly, the results of this study can lead to a better understanding of the ionic liquids as well as their utilization for other organic reactions.

EPFL2007

Ring-Opening Reactions of Aminocyclopropanes and Aminocyclobutanes

Mingming Wang

EPFL2022