Research

We are engaged in synthetic boron chemistry with an emphasis on expanding the chemical space of organic and biological small- and macro-molecules beyond what nature can achieve with boron-containing analogues.Ìý

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We are particularly interested in the development of boron(B)–nitrogen(N)-containing heterocycles, specifically azaborines. These are structures resulting from the replacement of two carbon atoms in benzene with a boron and aÌýnitrogen atom. Azaborines are isosteres of the important family of benzenoid compounds / arenes. TheyÌýclosely match the size and shape of ordinary benzene rings, and they still enjoy considerableÌýaromatic stabilization, but most of their other physical, chemical, and spectroscopic properties are significantly altered.ÌýWe aim to exploit the unique properties of azaborines and investigate their potential as arene surrogates in materials and biomedical research. Our approach combines the broad utility of arenes with the unique elementalÌýfeatures of boron. Areas of exploration include organic synthesis, catalysis, hydrogen storage, optoelectronic materials, and drug discovery. The development of azaborines has the potential of changing the way chemistsÌýthink about creating molecular diversity, namely through isosterism.

We are skilled in a variety of experimental techniques commonly applied in synthetic organic/organometallic chemistry, e.g., air-free Schlenk line and glovebox techniques for the preparation of our compounds, and X-Ray, NMR, MS, IR, UV-vis, HPLC, GC, electrochemistry for their characterization.