Your search keyword '"Patricia A. Mihm"' showing total 2 results

1. Collision‐induced dissociation of uranyl‐methoxide and uranyl‐ethoxide cations: Formation of UO 2 H + and uranyl‐alkyl product ions

Author

Patricia A. Mihm, Michael J. Van Stipdonk, Evan Perez, Theodore A. Corcovilos, Jordan Pestok, and Cassandra Hanley

Subjects

Collision-induced dissociation, 010401 analytical chemistry, Organic Chemistry, Analytical chemistry, Methoxide, 010402 general chemistry, Tandem mass spectrometry, Mass spectrometry, Uranyl, 01 natural sciences, Medicinal chemistry, Dissociation (chemistry), 0104 chemical sciences, Analytical Chemistry, chemistry.chemical_compound, chemistry, Fragmentation (mass spectrometry), Ion trap, Spectroscopy

Abstract

RATIONALE The lower levels of adventitious H2 O in a linear ion trap allow the fragmentation reactions of [UO2 OCH3 ](+) and [UO2 OCH2 CH3 ](+) to be examined in detail. METHODS Methanol- and ethanol-coordinated UO2 (2+) -alkoxide precursors were generated by electrospray ionization (ESI). Multiple-stage tandem mass spectrometry (MS(n) ) and collision-induced dissociation (CID) were performed using a linear ion trap mass spectrometer. RESULTS CID of [UO2 OCH3 (CH3 OH)n ](+) and [UO2 OCH2 CH3 (CH3 CH2 OH)n ](+) , n = 3 and 2, causes loss of neutral alcohol ligands, leading ultimately to bare uranyl-alkoxide species. Comparison of 'native' to deuterium-labeled precursors reveals dissociation pathways not previously observed in 3-D ion trap experiments. CONCLUSIONS UO2 H(+) is generated from [UO2 OCH3 ](+) by transfer of H from the methyl group. Variable-energy and variable-time CID experiments suggest that the apparent threshold for production of UO2 H(+) is lower than for UO2 (+) , but the pathway is kinetically less favored for the former than for the latter. CID experiments reveal that [UO2 OCH2 CH3 ](+) dissociates to generate [UO2 CH3 ](+) , a relatively rare species with a U-C bond, and [UO2 (O = CH2 )](+) .

Published

2016

2. Dissociation of gas-phase, doubly-charged uranyl-acetone complexes by collisional activation and infrared photodissociation

Author

Dean Martin, Alexandra Plaviak, Benjamin J. Bythell, Catherine O’Malley, Patricia A. Mihm, John K. Gibson, Jordan Pestok, Michael J. Van Stipdonk, Theodore A. Corcovilos, and Cassandra Hanley

Subjects

010401 analytical chemistry, Photodissociation, Analytical chemistry, 010402 general chemistry, Photochemistry, Mass spectrometry, Uranyl, Condensed Matter Physics, 01 natural sciences, Dissociation (chemistry), 0104 chemical sciences, chemistry.chemical_compound, chemistry, Fragmentation (mass spectrometry), Infrared multiphoton dissociation, Quadrupole ion trap, Physical and Theoretical Chemistry, Instrumentation, Ion cyclotron resonance, Spectroscopy

Abstract

Past studies of fragmentation reactions of doubly-charged uranyl (UO22+) complexes have been impeded by very rapid water addition reactions that cause H2O adducts to dominate product ion spectra. The fragmentation of uranyl-acetone (aco) complexes ([UO2(aco)n]2+, n = 1–5), generated by electrospray ionization, is revisited here using: (a) collisional activation in a linear ion trap (LIT) mass spectrometer in which the level of background H2O is significantly lower, and (b) infrared multiple-photon photodissociation (IRMPD, 10.6 μm) in the LIT and a Fourier-transform ion cyclotron resonance (FT-ICR) mass spectrometer. Lower levels of adventitious H2O in the LIT provided access to fragmentation of [UO2(aco)n]2+, n = 1–5. For n = 3–5, direct elimination of aco ligands is the favored fragmentation pathway. For n = 1 and 2, charge reduction reactions are dominant. For [UO2(aco)2]2+, the most abundant product ion is [UO2(aco)]+, while UO2+ is observed following collision-induced dissociation (CID) of [UO2(aco)]2+. Minor peaks corresponding to ligated [UO2OH]+ are also observed. The IRMPD experiments in the FT-ICR yielded highly accurate mass measurements that confirm composition assignments, and shed light on dissociation reactions in a gas-phase environment that is entirely free of adventitious H2O. For [UO2(aco)n]2+, n = 3–5, the primary photodissociation channel is direct aco elimination, along with charge-reduction pathways that involve intra-complex proton transfer and formation of species that contain enolate ligands. Similar pathways are observed for IRMPD measurements in the LIT.

Published

2016