One tool to bring them all: Au-catalyzed synthesis of B,O- and B,N-doped PAHs from boronic and borinic acids

The isoelectronic replacement of C=C bonds with B=N+ bonds in polycyclic aromatic hydrocarbons (PAHs) is a widely used tool to prepare novel optoelectronic materials. Far less well explored are corresponding 6,0-doped PAHs, although they have a similarly high application potential. We herein report on the modular synthesis of B,N- and 6,0-doped PAHs through the [Au(PPh3)NTf2]-catalyzed 6-endo-dig cyclization of BN-H and BO-H bonds across suitably positioned CC bonds in the key step. Readily available, easy-to-handle o-alkynylaryl boronic and borinic acids serve as starting materials, which are either cyclized directly or first converted into the corresponding aminoboranes and then cyclized. The reaction even tolerates bulky mesityl substituents on boron, which later kinetically protect the formed B,N/O-PAHs from hydrolysis or oxidation. Our approach is also applicable for the synthesis of rare doubly B,N/O-doped PAHs. Specifically, we prepared 1,2-6,E-naphthalenes and -anthracenes, 1,5-B 2 -2,6-E-2 -anthracenes (E = N, O) as well as B, O-2 -containing and unprecedented B,N,O-containing phenalenyls. Selected examples of these compounds have been structurally characterized by X-ray crystallography; their optoelectronic properties have been studied by cyclic voltammetry, electron spectroscopy, and quantum-chemical calculations. Using a new unsubstituted (B,O)(2)-perylene as the substrate for late-stage functionalization, we finally show that the introduction of two pinacolatoboryl (Bpin) substituents is possible in high yield and with perfect regioselectivity via an Ir-catalyzed C-H borylation approach.

Automated summary

The isoelectronic replacement of C=C bonds with B=N+ bonds in PAHs is a common method for preparing novel optoelectronic materials. This study reports the successful modular synthesis of B,N- and 6,0-doped PAHs through [Au(PPh3)NTf2]-catalyzed reactions, using easily accessible starting materials. The approach is also suitable for the synthesis of rare doubly doped PAHs, and the structural and optoelectronic properties of the compounds have been characterized.