Catalysis is highly important to all areas of modern life. It is estimated that 90% of all chemical process are catalysed, and the economic impact of catalysis is contributing 30–40% of global GDP. Today, the need for new technologies to address the change in use of raw materials and societal requirements has prompted chemists to re-evaluate how we approach chemical and refinery production, with a need for new catalysis approaches. High on the list is the need for new catalysis concepts and catalytic asymmetric reactions, novel or improved catalysts, and a better understanding of mechanisms applying structural, kinetic and computational studies. In this context, phase transfer catalysis (PTC) has proved advantageous. An outstanding challenge is the application of asymmetric catalysis to feedstock reagents as simple as inorganic salts that are not soluble in organic solvents, for example nucleophilic halogenation reagents such cost-effective KF.
The objective of this proposal was to provide solutions to this problem with a focus on fluorination with alkali metal fluoride and bio-inspired new concepts in catalysis, specifically Hydrogen Bonding Phase Transfer Catalysis (HBPTC). This was successfully achieved during the course of the proposal. Key accomplishments are the invention of new asymmetric catalytic processes for the fluorination of episulfonium, aziridinium, azetidinium, benzylic halide and alpha-halo carbonyls with KF in the presence of a chiral (bis)-urea catalyst or via synergistic dual catalysis. This new catalytic manifold was also extended to regiodivergent fluorination as well as inorganic nucleophiles other than alkali metal fluoride (e.g. sodium azide).
Rewardingly, our interest in enantioselective catalysis with alkali metal fluoride extended to the holygrail problem of fluorination with calcium fluoride. Exciting results were secured during the course of the project opening new opportunities for the manufacturing of fluorochemicals directly from acid grade fluorspar without the necessity to produce dangerous HF.