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Bond dissociation energies of transition metal oxides: CrO, MoO, RuO, and RhO

Jason J. Sorensen, Erick Tieu, Andrew Sevy, Dakota M. Merriles, Christopher Nielson, Joshua C. Ewigleben, Michael D. Morse

2020The Journal of Chemical Physics40 citationsDOI

Abstract

Through the use of resonant two-photon ionization spectroscopy, sharp predissociation thresholds have been identified in the spectra of CrO, MoO, RuO, and RhO. Similar thresholds have previously been used to measure the bond dissociation energies (BDEs) of many molecules that have a high density of vibronic states at the ground separated atom limit. A high density of states allows precise measurement of the BDE by facilitating prompt dissociation to ground state atoms when the BDE is exceeded. However, the number of states required for prompt predissociation at the thermochemical threshold is not well defined and undoubtedly varies from molecule to molecule. The ground separated atom limit generates 315 states for RuO, 252 states for RhO, and 63 states for CrO and MoO. Although comparatively few states derive from this limit for CrO and MoO, the observation of sharp predissociation thresholds for all four molecules nevertheless allows BDEs to be assigned as 4.863(3) eV (RuO), 4.121(3) eV (RhO), 4.649(5) eV (CrO), and 5.414(19) eV (MoO). Thermochemical cycles are used to derive the enthalpies of formation of the gaseous metal oxides and to obtain IE(RuO) = 8.41(5) eV, IE(RhO) = 8.56(6) eV, D0(Ru–O−) = 4.24(2) eV, D0(Cr–O−) = 4.409(8) eV, and D0(Mo–O−) = 5.243(20) eV. The mechanisms leading to prompt predissociation at threshold in the cases of CrO and MoO are discussed. Also presented is a discussion of the bonding trends for the transition metal oxides, which are compared to the previously measured transition metal sulfides.

Topics & Concepts

Bond-dissociation energyDissociation (chemistry)ChemistryTransition metalMoleculeGround stateIonizationAtomic physicsMetalAtom (system on chip)Ionization energyDensity functional theoryPhysical chemistryComputational chemistryPhysicsIonCatalysisEmbedded systemBiochemistryComputer scienceOrganic chemistryGas Sensing Nanomaterials and SensorsRadioactive element chemistry and processingCatalytic Processes in Materials Science