Exploration of transition metal-hydride compounds: Molecular structure, electronic properties, nonlinear optical characteristics, and reactivity of Cp-based binuclear ruthenium complexes

This paper reports a systematic DFT investigation of four Cp-bridged binuclear ruthenium complexes; Cp‡Ru(μ-H)₄RuCp‡ (A1), CpRu(μ-H)₂(μ-η²-C₆H₄O₂)RuCp (A2), CpRu(μ-B(N,N-dimethylphenylenediamine))(μ-H)₃RuCp (A3), and Cp‡Ru(μ-CCH₃)₂RuCp‡ (A4), employing B3LYP/Lanl2dz-6–31G(d,p), B3LYP/def2-TZVP, and PBE0/def2-TZVP levels of theory. Optimized geometries showed excellent agreement with experimental data: Ru–Ru bond lengths deviated within ±0.10 Å; Ru–Cp bonds were overestimated by 0.03–0.11 Å; and bond angles, such as Ru–(μ-H)–Ru, were reproduced within 3°, with PBE0/def2-TZVP showing the smallest deviation (0.1° for A4). Frontier molecular orbital analysis revealed A1 had the largest HOMO/LUMO gap, indicating high stability, while A2 exhibited the smallest, suggesting enhanced reactivity. Global reactivity results highlighted A3 with the lowest ionization potential, and A2 with the highest electron affinity, electronegativity, electrophilicity, softness, and chemical reactivity. MESP maps identified nucleophilic hydrides in A1 and A3, and nucleophilic zones on benzoquinone oxygens in A2. NBO analysis revealed strong metal-ligand delocalization with 4d⁸ Ru orbital occupations. A2 displayed orbital asymmetry and minor 2 s hydrogen contribution, indicating potential agostic bonding. A1 and A4 showed localized Ru–Ru and Ru–H bonding, while A2 and A3 exhibited more symmetric charge distributions. TD-DFT in acetonitrile showed that A1 excels as a high-energy light-harvesting candidate due to its strong MLCT and ILCT transitions, while A2 is ideal for red-shifted absorption applications. A3 and A4, with mixed charge transfer contributions, offer potential for multifunctional roles in optical devices and catalysis. NLO analysis identified A3 as most promising, with A2 showing highest dipole moment and A4 greatest polarizability. APT charges confirmed increasing negative Ru centers across methods, strong σ-donation from μ-CCH₃ in A4, π-backbonding in A2–A3, and a highly electron-deficient boron in A3 (+0.971), underscoring structure–property correlations relevant for optical and electronic design.