Cobalt, rhodium, and iridium dioxide molecules and Walsh-type rules

Zee, R. J. Van; Hamrick, Y. M.; Li, S.; Weltner, W.

doi:10.1021/j100197a022

Cited by 50 publications

(81 citation statements)

References 11 publications

(13 reference statements)

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“…[97] It is noteworthy that in the case of molybdenum, with seven isotopes of natural abundance greater than 9 %, it was possible to use 16 (symmetrical) 16 O 2 or 18 O 2 species to calculate an upper limit to the angle (1258), and more than 40 isotopomers to calculate a lower limit (1198). RuO 2 was reported [98] to have a bond angle of 1498, and if RhO 2 and IrO 2 are linear, as indicated by ESR measurements, [99] then the general pattern for the second-and third-row transition element dioxides appears to be similar to that established for the first row.…”

Section: Dioxidesmentioning

confidence: 83%

A Critical Appraisal of the Experimental Data on the Molecular Structure and Spectra of Halides, Oxides, and Hydrides of the s-, d-, and f-Block Elements

Beattie

1999

Angew. Chem. Int. Ed.

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Evidence for unusual shapes of simple MX(n) molecules that are not stable under normal conditions is critically appraised in this review, which assesses current knowledge of the spectra and structures of many simple binary halides, oxides, and hydrides. It emphasizes the need for more high-resolution gas-phase spectroscopic data, summarizes the current state of knowledge in many fields, and suggests key experiments that should be carried out to resolve conflicting results obtained in earlier studies.

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Section: Dioxidesmentioning

confidence: 83%

A Critical Appraisal of the Experimental Data on the Molecular Structure and Spectra of Halides, Oxides, and Hydrides of the s-, d-, and f-Block Elements

Beattie

1999

Angew. Chem. Int. Ed.

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“…A large number of experimental studies of inserted dioxides have been carried out on the mid-row transitionmetal dioxides, MnO 2 , [9][10][11] FeO 2 , [12][13][14] and CoO 2 . [15][16][17][18] Experimentally, the early-to mid-row transition-metal dioxides prefer bent structures, while the later transition-metal oxides have linear structures. The mid-row transition-metal oxides represent a formidable challenge for theoretical calculations, which, while extensive for MnO 2 , 19,20 FeO 2 ,8,[20][21][22] and CoO 2 , 20,23,24 have been inconclusive or contradictory with respect to experiment.…”

Section: Introductionmentioning

confidence: 99%

Transition-metal dioxides: A case for the intersite term in Hubbard-model functionals

Kulik

Marzari

2011

The Journal of Chemical Physics

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Triatomic transition-metal oxides in the "inserted dioxide" (O-M-O) structure represent one of the simplest examples of systems that undergo qualitative geometrical changes via subtle electronic-structure modulation. We consider here three transition-metal dioxide molecules (MO(2) where M = Mn, Fe, or Co), for which the equilibrium structural (e.g., bent or linear geometry) and electronic (e.g., spin or symmetry) properties have been challenging to assign both theoretically and experimentally. Augmenting a standard density-functional theory (DFT) approach with a Hubbard term (DFT+U) occasionally overlocalizes the 3d manifold, leading to an incorrect bond elongation and, in turn, poor equilibrium geometries for MO(2) molecules, while preserving good spin-state splittings. Proper description of both geometry and energetics for these molecules is recovered; however, through either calculating DFT+U relaxations at fixed M-O bond lengths or by inclusion of an intersite interaction term V that favors M(3d)-O(2p) interactions. In this latter case, both U and V are calculated fully from first-principles and are not fitting parameters. Finally, we identify an approach that more accurately determines the Hubbard U over a coordinate in which the covalent character of bonding varies.

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“…[28,29] The assignment of CoO 2 rather than Co + O 2 or CoO + O as the neutral product of Reaction (9) is based on ab initio studies of this system, which predict the dioxide CoO 2 as the energetically preferred species. [30,31] [(H 2 O)Co(NO 3 (9) Whereas Reaction (4) is a mere ligand loss from the hydrated monocation, Reaction (5) + as a function of collision energy; note that the secondary fragments are summed into the primary fragments. [32] Loss of a water ligand requires an appearance energy of AE(4) = (1.7 Ϯ 0.2) eV, a value which is right in the ballpark of water binding energies for bare or singly ligated metal cations, [20,27,33,34] lending confidence to the method for the approximate determination of appearance energies applied here.…”

Section: Introductionmentioning

confidence: 99%

Gas‐Phase Model Studies Relevant to the Decomposition of Transition‐Metal Nitrates M(NO₃)₂ (M = Co, Ni) into Metal–Oxo Species

2009

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Electrospray ionization (ESI) of aqueous cobalt(II) and nickel-(II) nitrate solutions inter alia affords the solvated, mono-and oligonuclear nitrato complexes [M m + (M = Co, Ni; m = 1-5; n = 1-4). The collision-induced dissociation spectra of the mass-selected ions imply that these ions correspond to genuine hydrated metal(II) nitrato complexes in that either cluster degradation through expulsion of neutral M(NO 3 ) 2 or sequential loss of water ligands take place. In the case of the lowest member of the series (m, n = 1), however, loss of water competes with homolytic cleavage of the N-O bond, which leads to the formation of [M,O 2 ,H 2 ] + cat-

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Cobalt, rhodium, and iridium dioxide molecules and Walsh-type rules

Cited by 50 publications

References 11 publications

A Critical Appraisal of the Experimental Data on the Molecular Structure and Spectra of Halides, Oxides, and Hydrides of the s-, d-, and f-Block Elements

A Critical Appraisal of the Experimental Data on the Molecular Structure and Spectra of Halides, Oxides, and Hydrides of the s-, d-, and f-Block Elements

Transition-metal dioxides: A case for the intersite term in Hubbard-model functionals

Gas‐Phase Model Studies Relevant to the Decomposition of Transition‐Metal Nitrates M(NO₃)₂ (M = Co, Ni) into Metal–Oxo Species

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Cobalt, rhodium, and iridium dioxide molecules and Walsh-type rules

Cited by 50 publications

References 11 publications

A Critical Appraisal of the Experimental Data on the Molecular Structure and Spectra of Halides, Oxides, and Hydrides of the s-, d-, and f-Block Elements

A Critical Appraisal of the Experimental Data on the Molecular Structure and Spectra of Halides, Oxides, and Hydrides of the s-, d-, and f-Block Elements

Transition-metal dioxides: A case for the intersite term in Hubbard-model functionals

Gas‐Phase Model Studies Relevant to the Decomposition of Transition‐Metal Nitrates M(NO3)2 (M = Co, Ni) into Metal–Oxo Species

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Gas‐Phase Model Studies Relevant to the Decomposition of Transition‐Metal Nitrates M(NO₃)₂ (M = Co, Ni) into Metal–Oxo Species