Electron affinities of the alkali halides and the structure of their negative ions

Thomas M. Miller; Doreen G. Leopold; Kermit K. Murray; W. C. Lineberger

doi:10.1063/1.451091

Electron affinities of the alkali halides and the structure of their negative ions

Thomas M. Miller, Doreen G. Leopold, Kermit K. Murray, W. C. Lineberger

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Abstract

Photoelectron spectra are reported for the MX (X̃ ¹∑ ⁺) + e^-←MX^-(X̃ ²∑ ⁺) transitions often alkali halide anions at 488 nm. Adiabatic electron affinities (±0.010 eV) are determined to be 0.593 (LiCl), 0.520 (NaF), 0.727 (NaCl), 0.788 (NaBr), 0.865 (NaI), 0.582 (KCl), 0.642 (KBr), 0.728 (KI), 0.543 (RbCl), and 0.455 eV (CsCl). Fundamental vibrational frequencies, equilibrium bond lengths, and dissociation energies are also reported for the anion 2Σ⁺ ground states. An observed linear correlation of electron affinities with α/r² (α = metal atom polarizability) is used to predict the electron affinities of the remaining alkali bromides and iodides, as well as related alkali salts. A simple electrostatic model for the alkali halide anions is also presented which enables the accurate (±0.1 eV) calculation of electron affinities.

Original language	English (US)
Pages (from-to)	2368-2375
Number of pages	8
Journal	The Journal of chemical physics
Volume	85
Issue number	5
DOIs	https://doi.org/10.1063/1.451091
State	Published - 1986
Externally published	Yes

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title = "Electron affinities of the alkali halides and the structure of their negative ions",

abstract = "Photoelectron spectra are reported for the MX ({\~X} 1∑ +) + e-←MX-({\~X} 2∑ +) transitions often alkali halide anions at 488 nm. Adiabatic electron affinities (±0.010 eV) are determined to be 0.593 (LiCl), 0.520 (NaF), 0.727 (NaCl), 0.788 (NaBr), 0.865 (NaI), 0.582 (KCl), 0.642 (KBr), 0.728 (KI), 0.543 (RbCl), and 0.455 eV (CsCl). Fundamental vibrational frequencies, equilibrium bond lengths, and dissociation energies are also reported for the anion 2Σ+ ground states. An observed linear correlation of electron affinities with α/r2 (α = metal atom polarizability) is used to predict the electron affinities of the remaining alkali bromides and iodides, as well as related alkali salts. A simple electrostatic model for the alkali halide anions is also presented which enables the accurate (±0.1 eV) calculation of electron affinities.",

author = "Miller, {Thomas M.} and Leopold, {Doreen G.} and Murray, {Kermit K.} and Lineberger, {W. C.}",

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T1 - Electron affinities of the alkali halides and the structure of their negative ions

AU - Miller, Thomas M.

AU - Leopold, Doreen G.

AU - Murray, Kermit K.

AU - Lineberger, W. C.

PY - 1986

Y1 - 1986

N2 - Photoelectron spectra are reported for the MX (X̃ 1∑ +) + e-←MX-(X̃ 2∑ +) transitions often alkali halide anions at 488 nm. Adiabatic electron affinities (±0.010 eV) are determined to be 0.593 (LiCl), 0.520 (NaF), 0.727 (NaCl), 0.788 (NaBr), 0.865 (NaI), 0.582 (KCl), 0.642 (KBr), 0.728 (KI), 0.543 (RbCl), and 0.455 eV (CsCl). Fundamental vibrational frequencies, equilibrium bond lengths, and dissociation energies are also reported for the anion 2Σ+ ground states. An observed linear correlation of electron affinities with α/r2 (α = metal atom polarizability) is used to predict the electron affinities of the remaining alkali bromides and iodides, as well as related alkali salts. A simple electrostatic model for the alkali halide anions is also presented which enables the accurate (±0.1 eV) calculation of electron affinities.

AB - Photoelectron spectra are reported for the MX (X̃ 1∑ +) + e-←MX-(X̃ 2∑ +) transitions often alkali halide anions at 488 nm. Adiabatic electron affinities (±0.010 eV) are determined to be 0.593 (LiCl), 0.520 (NaF), 0.727 (NaCl), 0.788 (NaBr), 0.865 (NaI), 0.582 (KCl), 0.642 (KBr), 0.728 (KI), 0.543 (RbCl), and 0.455 eV (CsCl). Fundamental vibrational frequencies, equilibrium bond lengths, and dissociation energies are also reported for the anion 2Σ+ ground states. An observed linear correlation of electron affinities with α/r2 (α = metal atom polarizability) is used to predict the electron affinities of the remaining alkali bromides and iodides, as well as related alkali salts. A simple electrostatic model for the alkali halide anions is also presented which enables the accurate (±0.1 eV) calculation of electron affinities.

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JO - The Journal of chemical physics

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Electron affinities of the alkali halides and the structure of their negative ions

Abstract

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