E. J. Campbell scite author profile

The microwave spectrum of the weakly bound complex benzene–HCl was studied in the gas phase using Fourier transform microwave spectroscopy carried out in a Fabry–Perot cavity with a pulsed supersonic nozzle as the molecular source. Several R-branch a-dipole transitions have been observed for benzene–H 35Cl, benzene–D 35Cl, benzene–H 37Cl, and benzene(d6)–H 35Cl. The spectrum was characteristic of a symmetric top, indicating that the time averaged displacement of the H and Cl atoms from the benzene C6 axis is zero. Deuterium substitution of HCl demonstrated that the acidic proton lies between the Cl atom and the benzene ring. The chlorine nuclear quadrupole coupling constant χClaa, was measured for all four isotopic species and is interpreted in terms of a projection of the chlorine quadrupole coupling constant in free HCl, averaged over two degenerate vibrational ground state bending modes involving the angles between the benzene C6 axis and the HCl bond axis. The spectroscopic constants for benzene–HCl are: aNumbers in parentheses represent one standard deviation in the fit.

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A new method for observing the rotational spectra of weak molecular complexes: KrHCl

Balle

Campbell

Keenan

et al. 1979

118

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A new method for observing the rotational spectra of weak molecular complexes: KrHCl

et al. 1980

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A new method of observing the rotational transitions of weak molecular complexes by combining the techniques of microwave Fourier transform spectroscopy, a Fabry–Perot cavity, and a pulsed nozzle source of molecules is described. High resolution and good sensitivity are achieved. Twelve isotopic species of the KrHCl molecule involving all combinations of the 86Kr, 84Kr, 82Kr, H, D, 35Cl, and 37Cl isotopes are assigned and the rotational constants, Cl nuclear quadrupole coupling constants, and centrifugal distortion constants are all given. The molecular structure indicates a linear equilibrium structure with the H(D) atom between the Kr and Cl atoms. However, the inverse moments of inertia measured here indicate large amplitude vibrations of the H(D) atom relative to the Kr–Cl internuclear line. Estimates of the Kr–Cl stretching frequency and force constants, which show considerable dependence on the isotopic species, are also given. Bending frequencies and force constants are also given.

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The vibrational ground state rotational spectroscopic constants and structure of the HCN dimer

1981

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Pulsed molecular-beam, diode-laser spectrometry using rapid scanning techniques

Piante

Campbell

Buelow

1989

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E. J. Campbell

The rotational spectrum and molecular structure of the benzene–hydrogen chloride complex

A new method for observing the rotational spectra of weak molecular complexes: KrHCl

A new method for observing the rotational spectra of weak molecular complexes: KrHCl

The vibrational ground state rotational spectroscopic constants and structure of the HCN dimer

Pulsed molecular-beam, diode-laser spectrometry using rapid scanning techniques

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