David P. Day scite author profile

The synthesis of bis(formazanate) zinc complexes is described. These complexes have well-behaved redox-chemistry, with the ligands functioning as a reversible electron reservoir. This allows the synthesis of bis(formazanate) zinc compounds in three redox states in which the formazanate ligands are reduced to "metallaverdazyl" radicals. The stability of these ligand-based radicals is a result of the delocalization of the unpaired electron over four nitrogen atoms in the ligand backbone. The neutral, anionic, and dianionic compounds (L2 Zn(0/-1/-2)) were fully characterized by single-crystal X-ray crystallography, spectroscopic methods, and DFT calculations. In these complexes, the structural features of the formazanate ligands are very similar to well-known β-diketiminates, but the nitrogen-rich (NNCNN) backbone of formazanates opens the door to redox-chemistry that is otherwise not easily accessible.

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Gold‐Catalyzed Cycloisomerizations of 1,n‐Diyne Carbonates and Esters

Day

Chan

2016

Adv Synth Catal

160

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Driven by the ever-growing need for efficient methods to prepare synthetically valuable complex molecules, homogeneous gold catalysis has emerged as an invaluable addition in the organic chemist's toolbox to achieve such goals. Within this field of catalysis, this review focuses on the contributions made toward the construction of core structural scaffolds found in bioactive natural products and pharmaceutical compounds from gold-catalyzed reactions of 1,n-diyne carbonates and esters. It covers the advances made through exploiting the reactivity of the substrate class triggered by an initial 1,2-or 1,3-acyloxy migration of the propargyl motif as well as one rare example of a concerted double cyclization pathway.

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“Janus” Calixarenes: Double-Sided Molecular Linkers for Facile, Multianchor Point, Multifunctional, Surface Modification

et al. 2016

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We herein report the synthesis of novel “Janus” calix[4]arenes bearing four “molecular tethering” functional groups on either the upper or lower rims of the calixarene. These enable facile multipoint covalent attachment to electrode surfaces with monolayer coverage. The other rim of the calixarenes bear either four azide or four ethynyl functional groups, which are easily modified by the copper(I)-catalyzed azide–alkyne cycloaddition reaction (CuAAC), either pre- or postsurface modification, enabling these conical, nanocavity reactor sites to be decorated with a wide range of substrates to impart desired chemical properties. Redox active species decorating the peripheral rim are shown to be electrically connected by the calixarene to the electrode surface in either “up” or “down” orientations of the calixarene.

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David P. Day

The Formazanate Ligand as an Electron Reservoir: Bis(Formazanate) Zinc Complexes Isolated in Three Redox States

Gold‐Catalyzed Cycloisomerizations of 1,n‐Diyne Carbonates and Esters

“Janus” Calixarenes: Double-Sided Molecular Linkers for Facile, Multianchor Point, Multifunctional, Surface Modification

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