The aim of this module is to broaden and extend the knowledge of modern Organic Chemistry so that students will be able to enter directly into a PhD or embark on a career as a specialist chemist.

By the end of the module students will have achieved a solid foundation in Organic Chemistry. In particular they will have a clear understanding of

• Main Group Organic Chemistry
• Organopalladium Chemistry

Lecture -

• Chemistry of Lithium Lithium amide bases, structure and aggregation of organolithiums. Use of sterically hindered bases in controlling enolate formation via kinetic deprotonation. R2NH effect. Lithium mediated cyclisation reactions. α-Heteroatom functionalised organolithiums.
• Chemistry of Boron Structure and synthesis of organoboranes. Hydroboration reaction. Reactions of organoboranes. Introduction of heteroatoms via borane intermediates. Allylboranes and boron enolates.
• Chemistry of Silicon Comparison of silicon and carbon compounds. Peterson olefination. Chemistry of vinyl, aryl silanes and allylsilanes. Silyl enol ethers, formation and reactions.
• Chemistry of Tin Synthesis of tin compounds. Transmetallation reactions. Chemistry of vinyl and allyl stannanes. Tin hydrides and their use in radical mediated reactions.

Organopalladium Chemistry

• Fundamental mechanistic steps Ligand variation, bonding modes, oxidative addition, reductive elimination, migratory insertion, carbonylation, β-hydride elimination.
• Palladium (II) catalysed C-C formation Heck simple and tandem processes, isomerisation. Nucleophilic addition to alkenes - Wacker, heterocycle synthesis, catalytic option.
• Palladium (0) catalysed bond formation C-C Stille and Suzuki couplings with optional carbonylation, Sonogashira alkyne coupling. C-X Formation of amines, sulfides, phosphines etc.
• π-allyl Complexes Alkylation, mechanism, stereo- and regiochemistry. Carbonates and epoxides - in situ base formation. Intramolecular examples.Trimethylenemethane complexes, [3+2] cycloadditions.