Theoretical Dissociation Energies for Ionic Molecules

Langhoff, Stephen R.; Bauschlicher, Charles W.; Partridge, Harry

doi:10.1007/978-94-009-5474-8_13

Cited by 3 publications

(4 citation statements)

References 106 publications

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“…Looking into another source of thermochemical data, CRC Handbook of Chemistry and Physics , we find the value of 86.8 ± 3.0 kcal/mol for the bond strength in MgO. Earlier ab initio calculations by Bauschlicher and co-workers resulted in 63.4 kcal/mol which is much closer to the QCISD(T)/6-311+G(3df) value than to the experimental results. The existing uncertainty concerning the bond strength and standard heat of formation for MgO prompted us to reinvestigate energetics of this molecule using highly accurate multireference configuration (MRCI) method …”

Section: Resultssupporting

confidence: 57%

Theoretical Study on the Reaction Mechanism of CO₂ with Mg

Hwang

Mebel

2000

J. Phys. Chem. A

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Ab initio QCISD(T)/6-311+G(3df)//MP2/6-31+G(d) calculations of potential energy surface for the reaction of Mg atoms with CO2 show that re-forming of carbon dioxide to carbon monoxide can be significantly enhanced in the presence of Mg atoms. The overall endothermicity of the Mg + CO2 → MgO + CO reaction is calculated to be about 66 kcal/mol, almost twice lower than the energy needed for spin-forbidden unimolecular decomposition of CO2 to CO + O(3P). The Mg + CO2 reaction is spin-allowed and the barrier, 68.8 kcal/mol, is greatly reduced as compared to the barrier for the unimolecular decomposition, 131 kcal/mol. The reaction proceeds via the MgOCO cyclic intermediate which lies 14.3 kcal/mol higher in energy than the reactants and stabilized with respect to Mg + CO2 by a barrier of 5.9 kcal/mol. The catalytic role of Mg atoms for re-forming of CO2 to CO is discussed. The reverse MgO + CO → Mg + CO2 reaction is highly exothermic and has a barrier of 2.8 kcal/mol indicating that magnesium oxide can be rapidly reduced by carbon monoxide producing Mg atoms and carbon dioxide. Highly accurate full valence active space MRCI calculations with extrapolation to the complete basis set allowed us to propose a new value for the standard heat of formation of MgO in the gas phase, 31.4−31.9 and 33.5−34.0 kcal/mol for ΔH f°(0 K) and ΔH f°(298 K), respectively. The result is 20 kcal/mol higher than the present recommended value and new experimental measurements of thermochemical data for gaseous MgO are suggested.

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Section: Resultssupporting

confidence: 57%

Theoretical Study on the Reaction Mechanism of CO₂ with Mg

Hwang

Mebel

2000

J. Phys. Chem. A

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“…The agreement between the Herzberg and Brewer and Brackett values (columns (g) and (h)) is striking and we have used the average of these values in our analyses. The measurements of Brewer and Brackett 43 are also in good agreement with theory 48 . We stress that our conclusions do not change when the other (slightly different) values are used.…”

Section: Resultssupporting

confidence: 88%

“…The measurements of Brewer and Brackett 43 are also in good agreement with theory. 48 We stress that our conclusions do not change when the other (slightly different) values are used.…”

Section: Reference Data For Gas-phase Alkali Halidesmentioning

confidence: 56%

Estimation of thermodynamic and physicochemical properties of the alkali astatides: On the bond strength of molecular astatine (At₂) and the hydration enthalpy of astatide (At⁻)

Burgers,

Zeneyedpour,

Luider

et al. 2024

J Mass Spectrom

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The recent accurate and precise determination of the electron affinity (EA) of the astatine atom At0 warrants a re‐investigation of the estimated thermodynamic properties of At0 and astatine containing molecules as this EA was found to be much lower (by 0.4 eV) than previous estimated values. In this contribution we estimate, from available data sources, the following thermodynamic and physicochemical properties of the alkali astatides (MAt, M = Li, Na, K, Rb, Cs): their solid and gaseous heats of formation, lattice and gas‐phase binding enthalpies, sublimation energies and melting temperatures. Gas‐phase charge‐transfer dissociation energies for the alkali astatides (the energy requirement for M+At− ➔ M0 + At0) have been obtained and are compared with those for the other alkali halides. Use of Born‐Haber cycles together with the new AE (At0) value allows the re‐evaluation of ΔHf (At0)g (=56 ± 5 kJ/mol); it is concluded that (At2)g is a weakly bonded species (bond strength <50 kJ/mol), significantly weaker bonded than previously estimated (116 kJ/mol) and much weaker bonded than I2 (148 kJ/mol), but in agreement with the finding from theory that spin‐orbit coupling considerably reduces the bond strength in At2. The hydration enthalpy (ΔHaq) of At− is estimated to be −230 ± 2 kJ/mol (using ΔHaq[H+] = −1150.1 kJ/mol), in good agreement with molecular dynamics calculations. Arguments are presented that the largest alkali halide, CsAt, like the smallest, LiF, will be only sparingly soluble in water, following the generalization from hard/soft acid/base principles that “small likes small” and “large likes large.”

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“…With the minimal VB structure set, the VB wave function correlates with restricted open-shell Hartree−Fock (ROHF) states of the TM + and H. Because the HF level treats poorly the atomic states and especially the 3d n +1 state, the deficiencies in the atomic calculation will carry over to the BDE values, even if the molecular calculation is correct. Goddard et al − and Bauschlicher et al , showed that the deficiencies can be avoided by correcting the energies of the TM + fragment using experimental atomic data. Thus, the TMH + species are dissociated into the atomic electronic states most closely resembling their situation in the molecule (i.e., for TM + it is the 4s 1 3d n state), and whenever necessary, the experimental atomic state splitting is used to correct the energy of the TM + fragment to the corresponding atomic ground state.…”

Section: Methodsmentioning

confidence: 99%

A Valence Bond Study of the Bonding in First Row Transition Metal Hydride Cations: What Energetic Role Does Covalency Play?

2000

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The transition metal hydride cations, TMH+ (TM = first transition metal row, Sc, Ti, V, Cr, Mn, Co, Ni, Cu, and Zn), have been studied using valence bond (VB) theory to elucidate the bonding in these systems through VB concepts. Although the bonds appear extremely covalent by virtue of charge distribution, this appearance conceals key contributions to bonding, such as covalent-ionic resonance energy (RECS) and relaxation energy of the inactive electrons (ΔE relax(inactive)). The RECS term is seen to increase from ScH+ toward ZnH+, becoming significant in the late TMH+ molecules. The ΔE relax(inactive) term, which accounts for the nonbonding 3d n electrons and the 3s23p6 core electrons, is always significant. Furthermore, for all of the bonds from CrH+ to CuH+, the relaxation term makes a major contribution to the bond energy. It appears therefore, that in these TM−H+ bonds, the spin pairing of the bonding electrons can act as a trigger for the nonbonding and adjacent core electrons to relax their Pauli repulsion and thereby strengthen the binding of TM+ and H. As a result of the general weakness of TM bonds, the relaxation is expected to frequently be an important bonding contribution. The major function of the inactive and core electrons shows that the traditional role of “covalency” must be reassessed in a systematic manner.

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Theoretical Dissociation Energies for Ionic Molecules

Cited by 3 publications

References 106 publications

Theoretical Study on the Reaction Mechanism of CO₂ with Mg

Theoretical Study on the Reaction Mechanism of CO₂ with Mg

Estimation of thermodynamic and physicochemical properties of the alkali astatides: On the bond strength of molecular astatine (At₂) and the hydration enthalpy of astatide (At⁻)

A Valence Bond Study of the Bonding in First Row Transition Metal Hydride Cations: What Energetic Role Does Covalency Play?

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Theoretical Dissociation Energies for Ionic Molecules

Cited by 3 publications

References 106 publications

Theoretical Study on the Reaction Mechanism of CO2 with Mg

Theoretical Study on the Reaction Mechanism of CO2 with Mg

Estimation of thermodynamic and physicochemical properties of the alkali astatides: On the bond strength of molecular astatine (At2) and the hydration enthalpy of astatide (At−)

A Valence Bond Study of the Bonding in First Row Transition Metal Hydride Cations: What Energetic Role Does Covalency Play?

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Theoretical Study on the Reaction Mechanism of CO₂ with Mg

Theoretical Study on the Reaction Mechanism of CO₂ with Mg

Estimation of thermodynamic and physicochemical properties of the alkali astatides: On the bond strength of molecular astatine (At₂) and the hydration enthalpy of astatide (At⁻)