Your search keyword '"Willard M. St. Iii John"' showing total 2 results

1. Low‐energy electron impact study of acetone

Author

Willard M. St. Iii John, John P. Doering, and Ron C. Estler

Subjects

Electron spectrometer, Spectrometer, General Physics and Astronomy, Spectral line, chemistry.chemical_compound, chemistry, Computer Science::Systems and Control, Acetone, Singlet state, Physical and Theoretical Chemistry, Atomic physics, Triplet state, Molecular beam, Electron ionization

Abstract

A low‐energy, high resolution, electron impact spectrometer with a molecular beam target has been constructed and used to study the electronic energy levels of acetone vapor. Similar spectra were also taken with a second electron spectrometer having a static gas target. Both sets of spectra are essentially identical and show the expected singlet states at 4.37, 6.35, and 7.45 eV, the first triplet state at 4.16 eV, and a very broad second triplet process from 5.3 to 6.1 eV with an intensity maximum at 5.88 eV. Attempts to resolve vibrational structure in the latter band were unsuccessful, even though vibrational spacings of 0.14 eV were easily resolved elsewhere in the spectrum.

Published

1974

2. ChemInform Abstract: LOW-ENERGY ELECTRON IMPACT STUDY OF ACETONE

Author

John P. Doering, Willard M. St. Iii John, and Ron C. Estler

Subjects

chemistry.chemical_compound, Electron spectrometer, chemistry, Spectrometer, Computer Science::Systems and Control, Acetone, General Medicine, Singlet state, Atomic physics, Triplet state, Molecular beam, Spectral line, Electron ionization

Abstract

A low‐energy, high resolution, electron impact spectrometer with a molecular beam target has been constructed and used to study the electronic energy levels of acetone vapor. Similar spectra were also taken with a second electron spectrometer having a static gas target. Both sets of spectra are essentially identical and show the expected singlet states at 4.37, 6.35, and 7.45 eV, the first triplet state at 4.16 eV, and a very broad second triplet process from 5.3 to 6.1 eV with an intensity maximum at 5.88 eV. Attempts to resolve vibrational structure in the latter band were unsuccessful, even though vibrational spacings of 0.14 eV were easily resolved elsewhere in the spectrum.

Published

1974