<i>Ab</i><i>initio</i> study on radical anions of nitro compounds

Ramondo, Fabio

doi:10.1139/v92-045

Cited by 22 publications

(16 citation statements)

References 27 publications

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“…Thus the nitrogen center is more than halfway toward tetrahedral geometry in the radical anions, as predicted by DFT. This pyramidalization has been predicted in earlier calculations [26,27]. Again, the explanation is rather straightforward.…”

Section: Compoundsupporting

confidence: 85%

Revisiting the heterogeneous electron-transfer kinetics of nitro compounds

Kraiya

Singh

Evans

2004

Journal of Electroanalytical Chemistry

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Section: Compoundsupporting

confidence: 85%

Revisiting the heterogeneous electron-transfer kinetics of nitro compounds

Kraiya

Singh

Evans

2004

Journal of Electroanalytical Chemistry

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“…The CN torsion frequency for the CH 3 NO 2 molecule corresponds to 2.6 meV and increases to 27 meV in the valence anion as a result of the tetrahedral structure of the ground state of the anion ͑increased hindrance of the torsional motion͒. 3 Thus we assign the ''breaks'' in the field detachment curves to field ionization of a mixed dipole-valence state in which the low energy torsional frequency gives rise to fast vibrational FIG. 5.…”

Section: Results and Conclusionmentioning

confidence: 83%

“…This is consistent with a number of theoretical and experimental studies of the nitromethane anion. 3,25 Since the main goal in performing these experiments was the determination of the adiabatic electron affinity of nitromethane, it was necessary to identify the origin ͑vЈϭ0, vЉϭ0͒ of the vibrational progressions for CH 3 NO 2 Ϫ and CD 3 NO 2 Ϫ spectra. The photoelectron spectra presented in Fig.…”

Section: Results and Conclusionmentioning

confidence: 99%

“…There, the following values of the EA's were reported: 0.43Ϯ0.2 and 0.35Ϯ0.2 eV for CH 3 NO 2 colliding with Cs and K atoms, respectively, and 0.39Ϯ0.2 eV for CD 3 NO 2 colliding with Cs atoms. Thus, we assign the peaks at the arrows marked on the spectra as the origin transitions for CH 3 ror bar in this case reflects the uncertainty in choosing the origin peak.…”

Section: Results and Conclusionmentioning

confidence: 99%

“…2 For the specific case of nitromethane, Adamowicz has calculated a dipole-bound electron affinity of Ϸ3 meV. Other studies 3 show that in the CH 3 NO 2 Ϫ valence state the -CNO 2 group becomes nonplanar with a dihedral angle of 148.5°between the NO 2 plane and the CN bond. Thus, the dipole and valence adiabatic states are coupled through a breakdown of the Born-Oppenheimer approximation perhaps as a result of the wagging motion of the -NO 2 group.…”

Section: Introductionmentioning

confidence: 99%

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On the binding of electrons to nitromethane: Dipole and valence bound anions

Compton¹,

Carman²,

Desfrançois³

et al. 1996

The Journal of Chemical Physics

199

218

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Articles you may be interested inDecay dynamics of nascent acetonitrile and nitromethane dipole-bound anions produced by intracluster chargetransfer J.Low-energy photoelectron imaging spectroscopy of nitromethane anions: Electron affinity, vibrational features, anisotropies, and the dipole-bound state J. Chem. Phys. 130, 074307 (2009); 10.1063/1.3076892 Dipole bound and valence state coupling in argon-solvated nitromethane anionsConventional ͑valence͒ and dipole-bound anions of the nitromethane molecule are studied using negative ion photoelectron spectroscopy, Rydberg charge exchange and field detachment techniques. Reaction rates for charge exchange between Cs(ns,nd) and Xe(n f ) Rydberg atoms with CH 3 NO 2 exhibit a pronounced maximum at an effective quantum number of n*Ϸ13Ϯ1 which is characteristic of the formation of dipole-bound anions ͓͑CH 3 NO 2 ͒ϭ3.46 D͔. However, the breadth ͑⌬nϷ5, FWHM͒ of the n-dependence of the reaction rate is also interpreted to be indicative of direct attachment into a valence anion state via a ''doorway'' dipole anion state. Studies of the electric field detachment of CH 3 NO 2 Ϫ formed through the Xe(n f ) reactions at various n values provide further evidence for the formation of both a dipole-bound anion as well as a contribution from the valence bound anion. Analysis of the field ionization data yields a dipole electron affinity of 12Ϯ3 meV. Photodetachment of CH 3 NO 2 Ϫ and CD 3 NO 2 Ϫ formed via a supersonic expansion nozzle ion source produces a photoelectron spectrum with a long vibrational progression indicative of a conventional ͑valence bound͒ anion with a substantial difference in the equilibrium structure of the anion and its corresponding neutral. Assignment of the origin ͑vЈϭ0, vЉϭ0͒ transitions in the photoelectron spectra of CH 3 NO 2 Ϫ and CD 3 NO 2 Ϫ yields adiabatic electron affinities of 0.26Ϯ0.08 and 0.24Ϯ0.08 eV, respectively.

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