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Multiple Bonding in Rhodium Monoboride. Quasi-atomic Analyses of the Ground and Low-Lying Excited States

George Schoendorff, Klaus Ruedenberg, Mark S. Gordon

2021The Journal of Physical Chemistry A21 citationsDOIOpen Access PDF

Abstract

The bonding structures of the ground state and the lowest five excited states of rhodium monoboride are identified by determining the quasi-atomic orbitals in full valence space MCSCF wave functions and the interactions between these orbitals. A quadruple bond, namely two π-bonds and two σ-bonds, is identified and characterized for the X1Σ+ ground state, in agreement with a previous report (Cheung J. Phys. Chem. Lett. 2020, 11, 659−663). However, in all excited states, the bonding is predicted to be weaker because, in these states, one of the σ-bonding interactions has a small magnitude. In the a3Δ and A1Δ states, the bond order is between a triple and quadruple bond. In the b3Σ+ state, the Rh–B linkage is a triple bond. In the c3Π and B1Π states, the atoms are linked by a double bond due to an additional weakening of the two π-bonds. The decreases in the predicted bond strengths are reflected in the decreases of the predicted binding energies and in the increases of the predicted bond lengths from the X1Σ+ ground state to the c3Π and the B1Π excited states. Notably, the 5pσ orbital of rhodium, which is vacant in the ground state of the atom, plays a significant role in the molecule.

Topics & Concepts

Excited stateChemistryBond orderGround stateThree-center two-electron bondRhodiumAtomic physicsBond lengthValence bond theoryAtomic orbitalTriple bondSingle bondAtom (system on chip)Bond strengthBond energyMolecular orbitalMoleculeCrystallographyDouble bondPhysicsGroup (periodic table)ElectronCrystal structureQuantum mechanicsCatalysisComputer scienceOrganic chemistryBiochemistryAdhesiveEmbedded systemPolymer chemistryLayer (electronics)Molecular Junctions and NanostructuresAdvanced Chemical Physics StudiesInorganic Chemistry and Materials