Generation and characterization of ionic and neutral P(OH) 2+/· in the gas phase by tandem mass spectrometry and computational chemistry

The bicoordinated dihydroxyphosphenium ion P(OH) 2 + ( 1 +) was generated specifically by charge-exchange dissociative ionization of triethylphosphite and its connectivity was confirmed by collision induced dissociation and neutralization-reionization mass spectra. The major dissociation of 1 + form...

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Bibliographic Details
Published in:Journal of the American Society for Mass Spectrometry 2002-03, Vol.13 (3), p.250-264
Main Authors: Srikanth, R, Srinivas, R, Bhanuprakash, K, Vivekananda, S, Syrstad, E.A, Turec̆ek, F
Format: Article
Language:English
Subjects:
Atomic and molecular physics
Bond strengths, dissociation energies
Charge exchange
Chemical bonds
Cleavage
Collision dynamics
Computational chemistry
Configuration interaction
Density functional theory
Electron transfer
Electrons
Exact sciences and technology
Hydrogen bonds
Internal conversion
Ionization
Isomerization
Mass spectra
Mass spectrometry
Mathematical analysis
Molecular properties and interactions with photons
Physics
Properties of molecules and molecular ions
Time measurement
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Summary:The bicoordinated dihydroxyphosphenium ion P(OH) 2 + ( 1 +) was generated specifically by charge-exchange dissociative ionization of triethylphosphite and its connectivity was confirmed by collision induced dissociation and neutralization-reionization mass spectra. The major dissociation of 1 + forming PO + ions at m/ z 47 involved another isomer, OPOH 2 + ( 2 +), for which the optimized geometry showed a long POH 2 bond. Dissociative 70-eV electron ionization of diethyl phosphite produced mostly 1 + together with a less stable isomer, HP(O)OH + ( 3 +). Ion 2 + is possibly co-formed with 1 + upon dissociative 70-eV electron ionization of methylphosphonic acid. Neutralization-reionization of 1 + confirmed that P(OH) 2 · ( 1) was a stable species. Dissociations of neutral 1, as identified by variable-time measurements, involved rate-determining isomerization to 2 followed by fast loss of water. A competitive loss of H occurs from long-lived excited states of 1 produced by vertical electron transfer. The A and B states undergo rate-determining internal conversion to vibrationally highly excited ground state that loses an H atom via two competing mechanisms. The first of these is the direct cleavage of one of the OH bonds in 1. The other is an isomerization to 3 followed by cleavage of the PH bond to form OPOH as a stable product. The relative, dissociation, and transition state energies for the ions and neutrals were studied by ab initio and density functional theory calculations up to the QCISD(T)/6–311+G(3df,2p) and CCSD(T)/aug-cc-pVTZ levels of theory. RRKM calculations were performed to investigate unimolecular dissociation kinetics of 1. Excited state geometries and energies were investigated by a combination of configuration interaction singles and time-dependent density functional theory calculations.
ISSN:1044-0305
1879-1123
DOI:10.1016/S1044-0305(01)00360-9