The maximum bond order between two main-group atoms was known to be three. However, it has been suggested recently that there is quadruple bonding in C 2 and analogous eight-valence electron species. While the quadruple bond in C 2 has aroused some debates, an interesting question is: are main-group elements capable of forming quadruple bonds? Here we use photoelectron spectroscopy and computational chemistry to probe the electronic structure and chemical bonding in RhB 2 O − and RhB − and show that the boron atom engages in quadruple bonding with rhodium in RhB(BO) − and neutral RhB. The quadruple bonds consist of two πbonds formed between the Rh 4d xz /4d yz and B 2p x /2p y orbitals and two σ-bonds between the Rh 4d z 2 and B 2s/2p z orbitals. To confirm the quadruple bond in RhB, we also investigate the linear RhB−H + species and find a triple bond between Rh and B, which has a longer bond length, lower stretching frequency, and smaller bond dissociation energy in comparison with that of the Rh≣B quadruple bond in RhB.
A tubular molecular rotor B-Ta@B (1) and boron drum Ta@B (2) with the highest coordination number of twenty in chemistry are observed via a joint photoelectron spectroscopy and first-principles theory investigation.
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