Proton-bound cluster ions in ion mobility spectrometry

Gaseous oxygen and nitrogen bases, both singly and as binary mixtures, have been introduced into ion mobility spectrometers to study the appearance of protonated molecules, and proton-bound dimers and trimers. At ambient temperature it was possible to simultaneously observe, following the introducti...

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Bibliographic Details
Published in:International journal of mass spectrometry 1999-10, Vol.193 (1), p.57-68
Main Authors: Ewing, Robert G, Eiceman, Gary A, Stone, J.A
Format: Article
Language:English
Subjects:
Air - analysis
Alcohols - analysis
Alcohols - chemistry
Asymmetric
Dimerization
Gases - analysis
Hydrocarbons - analysis
Hydrocarbons - chemistry
Hydrogen Bonding
Ion mobility spectrometry
Ions
Life Sciences (General)
Mass Spectrometry
Nitrogen - analysis
Nitrogen - chemistry
Oxygen - analysis
Oxygen - chemistry
Proton-bound dimer
Protons
Space life sciences
Temperature
Thermodynamics
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Summary:Gaseous oxygen and nitrogen bases, both singly and as binary mixtures, have been introduced into ion mobility spectrometers to study the appearance of protonated molecules, and proton-bound dimers and trimers. At ambient temperature it was possible to simultaneously observe, following the introduction of molecule A, comparable intensities of peaks ascribable to the reactant ion (H 2O) n H +, the protonated molecule AH + and AH + · H 2O, and the symmetrical proton bound dimer A 2H +. Mass spectral identification confirmed the identifications and also showed that the majority of the protonated molecules were hydrated and that the proton-bound dimers were hydrated to a much lesser extent. No significant peaks ascribable to proton-bound trimers were obtained no matter how high the sample concentration. Binary mixtures containing molecules A and B, in some cases gave not only the peaks unique to the individual compounds but also peaks due to asymmetrical proton bound dimers AHB +. Such ions were always present in the spectra of mixtures of oxygen bases but were not observed for several mixtures of oxygen and nitrogen bases. The dimers, which were not observable, notable for their low hydrogen bond strengths, must have decomposed in their passage from the ion source to the detector, i.e. in a time less than ∼5 ms. When the temperature was lowered to −20 °C, trimers, both homogeneous and mixed, were observed with mixtures of alcohols. The importance of hydrogen bond energy, and hence operating temperature, in determining the degree of solvation of the ions that will be observed in an ion mobility spectrometer is stressed. The possibility is discussed that a displacement reaction involving ambient water plays a role in the dissociation.
ISSN:1387-3806
0168-1176
1873-2798
DOI:10.1016/S1387-3806(99)00141-4