Synthesis of BN-Polyarenes by a Mild Borylative Cyclization Cascade

BN-embedded aromatic hydrocarbons: synthesis, functionalization and applications

Substituting CC double bonds with B-N bonds in polycyclic aromatic hydrocarbons (PAHs) has emerged as a promising approach to advance and diversify organic functional materials. This structural modification not only imparts unique electronic and optical properties, but also enhances chemical stability, thereby opening new avenues for material design and applications. However, the widespread adoption of BN-fused aromatic hydrocarbons in practical applications is still in its nascent phase. This constraint stems primarily from the challenges in precisely tailoring molecular structures to optimize photophysical and electronic properties, thereby influencing their efficacy in targeted applications. Consequently, a comprehensive evaluation of historical, current, and prospective developments in BN-fused aromatic hydrocarbons is deemed essential. This review offers an in-depth overview of recent advancements in BN-fused aromatic hydrocarbons, focusing on synthetic strategies, fundamental properties, and emerging applications. Additionally, we elucidate the pivotal role of computational chemistry in directing the design, discovery, and optimization of these materials. Our objective is to foster interdisciplinary collaboration and stimulate innovative approaches to fully harness the potential of azaborinine chemistry across various fields, including organic optoelectronics, biomedicine, and related disciplines.

N-Directed Two-Fold Bromoboration of Diynes Enables Access to Brominated BN-Embedded PAHs

N-directed 2-fold bromoboration reactions of diynes with BBr3 have been developed, allowing the access to novel internally BN-doped polycyclic aromatic hydrocarbons from readily available precursors under mild conditions. Computational investigations identified three potential reaction mechanisms, each involving either BBr3 or [BBr4]-, with low activation barriers (ΔG‡ < 16 kcal/mol) for all pathways. The resulting brominated products can be further functionalized through various cross-coupling protocols, enabling the synthesis of highly luminescent emitters with quantum yield exceeding 90.

Selective Synthesis of Boron-Functionalized Indenes and Benzofulvenes by BCl3-Promoted Cyclizations of ortho-Alkynylstyrenes

A selective, metal-free synthesis of boron-functionalized indenes and benzofulvenes via BCl3-mediated cyclization of o-alkynylstyrenes is described. The method allows precise control over product formation by adjusting reaction conditions. These borylated products were utilized in diverse C-B bond derivatizations and in the total synthesis of Sulindac, a nonsteroidal anti-inflammatory drug, demonstrating the versatility and practicality of the developed methodology for synthetic applications.

From propenolysis to enyne metathesis: tools for expedited assembly of 4a,8a-azaboranaphthalene and extended polycycles with embedded BN

The synthesis of BN-containing molecules, which have an interesting isosteric relationship to their parent all-C cores, has drawn a great deal of attention as an avenue to alter and tune molecular function. Nevertheless, many cores with embedded BN are still hard to synthesize, and thus, further effort is required in this direction. Herein, we present an integrated approach to BN-containing polycycles rooted in an exceptionally clean B-N condensation of amines with a tri-allylborane. Having released propene as the only byproduct, the resulting BN precursors are seamlessly telescoped into BN-containing polycyclic cores via a set of additional methodologies, either developed here ad-hoc or applied for the first time for the synthesis of BN-cycles. As the "sharpening stone" of the process, BN-embedded naphthalene, which has previously only been obtained in low yield, can now be synthesized efficiently through propenolysis, ring-closing metathesis and a new high-yielding aromatization. As a more advanced application, an analogously obtained BN-containing bis-enyne is readily converted to BN-containing non-aromatic tetra-, penta- and hexacyclic structures via ring-closing enyne metathesis, followed by the Diels-Alder cycloaddition. The resulting air-sensitive structures are easily handled by preventive hydration (quaternization) of their B-N bridge; reverting this hydration restores the original Bsp2-Nsp2 structure. In the future, these structures may pave the way to BN-anthracenes and other π-extended BN-arenes.