| Summary: | <p>The first section of this dissertation (Chapter I-III) describes the development of new methodologies for the rhodium catalyzed C-N bond formation between sp<sup>3</sup> hybridized carbon atom of phenyl substituted alpha-lactams and the nitrogen atom of indole derivatives. Phenyl substituted alpha-lactams generated <I>in situ</I> from the corresponding alpha-bromoamides reacted with indoles in the presence of rhodium catalyst to afford the ring opening products of alpha-lactams. The scope of this methodology was extended to various types of indole derivatives including electron donating and withdrawing substituents. Furthermore, a series of functionalized phenyl substituted alpha-lactams generated <I>in situ</I> reacted with indole to assess the viability of this methodology. The developed method provides an atom-economical approach for the formation of substituted alpha-amino amides in good to excellent yields. </p>
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The main goal of the research described in the second section (Chapter IV-VII) is the synthesis of the corannulene-based molecular receptors with polar tethers and their immobilization on silica gel. First, we have considered a preparation of bis-corannulenoanthracene, formally possessing the pentacene core as a potential precursor for a series of barrelene based bis-corannulene receptors with polar groups. Bis-corannulenoanthracene was synthesized by the double Diels-Alder cycloaddition of isocorannulenofuran with bis-benzyne precursor, followed by deoxygenation of the endoxide adducts. While bis-corannulenoanthracene is stable enough to be isolated and stored, its pentacene core undergoes facile cycloaddition with maleic anhydride to afford bis-corannulene molecular receptor with the barrelene tether adorned with the anhydride moiety. The <sup>1</sup>H NMR titration experiments carried out in chlorobenzene-<I>d<sub>5</sub></I> proved the high binding affinity of the receptor toward C<sub>60</sub>. In addition, the presence of polar anchors on its tether allowed for its deposition on silica gel through the (3-aminopropyl)triethoxysilane linker.
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