Predicting Dinitrogen Activation by Boron Radical Cations
Activation of dinitrogen (N2) under mild conditions has been a particularly challenging project for decades, owing to the highly strong N≡N triple bond. In recent years, the main group species have emerged as a prominent strategy in the field of dinitrogen activation, but the reported examples remain particularly rare compared with transition metal complexes. Herein, we performed a comprehensive density functional theory (DFT) calculation of N2 activation by boron radical cations. The calculations demonstrated that N2 activation by boron radical cations was favorable both kinetically and thermodynamically, with high exothermicity (ΔG value of −36.8 kcal/mol) and a low reaction barrier (7.3 kcal/mol), indicating feasibility under mild conditions. Moreover, principal interacting spin orbitals (PISOs) and intrinsic bond orbitals (IBOs) analyses revealed that the boron radical cation activated N2 through two perpendicular interactions, including σ-type donation and π-type backdonation. Additionally, further analysis implied that π-type backdonation is essential for N2 activation. Our findings offer an alternative approach for metal-free N2 activation, highlighting the significance of boron chemistry in N2 activation.