<p> The organic ions studied in this thesis were generated in the rarefied gas phase of the mass spectrometer by electron ionization of selected precursor molecules. The characterization of their structure and reactivity was probed by using a variety of tandem mass spectrometry techniques. These include metastable ion spectra to probe the dissociation chemistry of the low energy ions and collision experiments to establish the atom connectivity of the ions. The technique of neutralization-reionization mass spectrometry (NRMS) was used to probe the structure and stability of the neutral counterparts of the ions. Computational results involving the CBS-QB3 model chemistry formed an integral component in the interpretation of the experimental findings.</p> <p> The above approach was used to study proton-transport catalysis in the formaldehyde elimination from low energy 1,3-dihydroxyacetone radical cations. Solitary ketene-water ions, CH2=C(=O)OH2·+, do not readily isomerize into its more stable isomer, CH2=C(OH)2·+. A mechanistic analysis using the CBS-QB3 model chemistry shows that metastable 1,3-dihydroxyacetone radical cations will rearrange into hydrogen-bridged radical cations [CH2C(=O)O(H)-H•••OCH2]·+, where the CH2=O will catalyze the
transformation of CH2=C(=O)OH2·+ into CH2=C(OH)2·+.</p> <p> Metastable pyruvic acid radical cations, CH3C(=O)COOH·+, have been shown to undergo decarboxylation to yield m/z 44 ions, C2H4O·+, in competition with the formation of CH3C=O+ + COOH· by direct bond cleavage. Collision induced dissociation experiments agree with an earlier report that oxycarbene ions CH3COH·+ are formed but they also suggest the more stable isomer CH3C(H)=O·+ may be co-generated. Using the CBS-QB3 model chemistry, a mechanism is proposed to rationalize these results.</p> <p> Next, the isomeric ions CH3O-P=S·+ and CH3S-P=O·+ were characterized and differentiated by tandem mass spectrometry. Metastable CH3O-P=S·+ and CH3S-P=O·+ ions both spontaneously lose water to yield m/lz 74 cyclic product ion [-S-CH=]P·+. Using the CBS-QB3 model chemistry a mechanism is proposed for the water loss from CH3O-P=S·+ and CH3S-P=O·+. Our calculations also show that these two isomers communicate via a common intermediate, the distonic ion CH2S-P-OH·+, prior to the loss of water.</p> <p> The final component of this work details the computational study addressing the long standing question on the mechanism for the water elimination from metastable ethyl acetate radical cations. The CBS-QB3 results show that low energy ethyl acetate ions isomerize into ionized 4-hydroxy-2-butanone prior to the loss of water.</p> / Thesis / Master of Science (MSc)
| Identifer | oai:union.ndltd.org:mcmaster.ca/oai:macsphere.mcmaster.ca:11375/21367 |
| Date | 09 1900 |
| Creators | Lee, Richard |
| Contributors | Terlouw, Johan K., Chemistry |
| Source Sets | McMaster University |
| Language | en_US |
| Detected Language | English |
| Type | Thesis |
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