Charge-induced structural transition between seashell-like B29- and B29+ in 18 p-electron configurations  

      Recent joint experimental and theoretical investigations have shown that seashell-like C₂ B₂₈ is the smallest neutral borospherene reported to date, while seashell-like C_s B₂₉^- (1^-) as a minor isomer competes with its quasi-planar counterparts in B29^- cluster beams. Extensive global minimum searches and first-principles theory calculations performed in this work indicate that with two valence electrons detached from B₂₉, the B₂₉+ monocation favors a seashell-like C_s B₂₉⁺ (1⁺) much different from C_sB₂₉^- (1^-) in geometry which is overwhelmingly the global minimum of the system with three B7 heptagonal holes in the front, on the back, and at the bottom, respectively, unveiling an interesting charge-induced structural transition from C_s B₂₉^- (1^-) to C_s B₂₉⁺ (1⁺). Detailed bonding analyses show that with one less σ bond than B₂₉^- (1^-), C_s B₂₉⁺ (1⁺) also possesses nine delocalized p-bonds over its s-skeleton on the cage surface with a σ + π double delocalization bonding pattern and follows the 2(n + 1)² electron counting rule for 3D spherical aromaticity (n = 2). B₂₉⁺ (1⁺) is therefore the smallest borospherene monocation reported to date which is p-isovalent with the smallest neutral borospherene C₂ B₂₈. The IR, Raman, and UV-vis spectra of B₂₉⁺ (1+ ) are computationally simulated to facilitate its spectroscopic characterization.