Your search keyword '"Luke J. Metzler"' showing total 6 results

1. Destruction and reconstruction of UO22+ using gas-phase reactions

Author

Amanda R. Bubas, Evan Perez, Theodore A. Corcovilos, Árpád Somogyi, Luke J. Metzler, and Michael J. Van Stipdonk

Subjects

010405 organic chemistry, Ligand, Decarboxylation, General Physics and Astronomy, 010402 general chemistry, Uranyl, Cleavage (embryo), Tandem mass spectrometry, 01 natural sciences, Medicinal chemistry, Dissociation (chemistry), 0104 chemical sciences, Ion, chemistry.chemical_compound, chemistry, Physical and Theoretical Chemistry, Fluoride

Abstract

While the strong axial UO bonds confer high stability and inertness to UO22+, it has been shown that the axial oxo ligands can be eliminated or replaced in the gas-phase using collision-induced dissociation (CID) reactions. We report here tandem mass spectrometry experiments initiated with a gas-phase complex that includes UO22+ coordinated by a 2,6-difluorobenzoate ligand. After decarboxylation to form a difluorophenide coordinated uranyl ion, [UO2(C6F2H3)]+, CID causes elimination of CO, and then CO and C2H2 in sequential dissociation steps, to leave a reactive uranium fluoride ion, [UF2(C2H)]+. Reaction of [UF2(C2H)]+ with CH3OH creates [UF2(OCH3)]+, [UF(OCH3)2]+ and [UF(OCH3)2(CH3OH)]+. Cleavage of C–O bonds within these species results in the elimination of methyl cation (CH3+). Subsequent CID steps convert [UF(OCH3)2]+ to [UO2(F)]+ and similarly, [U(OCH3)3]+ to [UO2(OCH3)]+. Our experiments show removal of both uranyl oxo ligands in “top-down” CID reactions and replacement in “bottom-up” ion–molecule and dissociation steps.

Published

2021

2. Formation and hydrolysis of gas-phase [UO2 (R)]+ : R═CH3 , CH2 CH3 , CH═CH2 , and C6 H5

Author

Susan Kline, Amanda R. Bubas, Luke J. Metzler, Michael J. Van Stipdonk, Irena Tatosian, and Anna Iacovino

Subjects

Collision-induced dissociation, 010405 organic chemistry, Decarboxylation, Chemistry, Radical, 010401 analytical chemistry, Ketene, 01 natural sciences, Medicinal chemistry, Dissociation (chemistry), 0104 chemical sciences, Ion, chemistry.chemical_compound, Hydrolysis, Density functional theory, Spectroscopy

Abstract

The goals of the present study were (a) to create positively charged organo-uranyl complexes with general formula [UO2 (R)]+ (eg, R═CH3 and CH2 CH3 ) by decarboxylation of [UO2 (O2 C─R)]+ precursors and (b) to identify the pathways by which the complexes, if formed, dissociate by collisional activation or otherwise react when exposed to gas-phase H2 O. Collision-induced dissociation (CID) of both [UO2 (O2 C─CH3 )]+ and [UO2 (O2 C─CH2 CH3 )]+ causes H+ transfer and elimination of a ketene to leave [UO2 (OH)]+ . However, CID of the alkoxides [UO2 (OCH2 CH3 )]+ and [UO2 (OCH2 CH2 CH3 )]+ produced [UO2 (CH3 )]+ and [UO2 (CH2 CH3 )]+ , respectively. Isolation of [UO2 (CH3 )]+ and [UO2 (CH2 CH3 )]+ for reaction with H2 O caused formation of [UO2 (H2 O)]+ by elimination of ·CH3 and ·CH2 CH3 : Hydrolysis was not observed. CID of the acrylate and benzoate versions of the complexes, [UO2 (O2 C─CH═CH2 )]+ and [UO2 (O2 C─C6 H5 )]+ , caused decarboxylation to leave [UO2 (CH═CH2 )]+ and [UO2 (C6 H5 )]+ , respectively. These organometallic species do react with H2 O to produce [UO2 (OH)]+ , and loss of the respective radicals to leave [UO2 (H2 O)]+ was not detected. Density functional theory calculations suggest that formation of [UO2 (OH)]+ , rather than the hydrated UV O2+ , cation is energetically favored regardless of the precursor ion. However, for the [UO2 (CH3 )]+ and [UO2 (CH2 CH3 )]+ precursors, the transition state energy for proton transfer to generate [UO2 (OH)]+ and the associated neutral alkanes is higher than the path involving direct elimination of the organic neutral to form [UO2 (H2 O)]+ . The situation is reversed for the [UO2 (CH═CH2 )]+ and [UO2 (C6 H5 )]+ precursors: The transition state for proton transfer is lower than the energy required for creation of [UO2 (H2 O)]+ by elimination of CH═CH2 or C6 H5 radical.

Published

2019

3. Formation of [Cu(CO2)(CH3OH)]+ and [Cu(N2)(CH3OH)]+ by gas-phase dissociation and exchange reactions

Author

Michael J. Van Stipdonk, Stephen Koehler, Árpád Somogyi, and Luke J. Metzler

Subjects

Decarboxylation, Electrospray ionization, 010401 analytical chemistry, 010402 general chemistry, Condensed Matter Physics, Tandem mass spectrometry, 01 natural sciences, Dissociation (chemistry), 0104 chemical sciences, Ion, Isotopic labeling, chemistry.chemical_compound, chemistry, Physical chemistry, Density functional theory, Methanol, Physical and Theoretical Chemistry, Instrumentation, Spectroscopy

Abstract

Electrospray ionization and multiple-stage tandem mass spectrometry were used to study the collision-induced dissociation of methanol-coordinated copper-acetate cations, and the ion-molecule reactions of specific product ions. Our experiments led to the discovery of unusual gas-phase ions with compositions such as [Cu(CO2)(CH3OH)]+ and [Cu(N2)(CH3OH)]+. The latter is generated by spontaneous exchange of CO2 for N2 in an ion-molecule reaction. Isotopic labeling studies and high mass-resolution measurements provide data to support the product ion composition assignments. Density functional theory calculations corroborate the experimental observations, both with respect to the preferential decarboxylation over methanol ligand elimination, and the spontaneous nature of the ion-molecule reactions.

Published

2019

4. Collision‐induced dissociation of [UO 2 (NO 3 ) 3 ] − and [UO 2 (NO 3 ) 2 (O 2 )] − and reactions of product ions with H 2 O and O 2

Author

Amanda R. Bubas, Evan Perez, Michael J. Van Stipdonk, Scott D. Rissler, and Luke J. Metzler

Subjects

Collision-induced dissociation, 010405 organic chemistry, Chemistry, Electrospray ionization, 010401 analytical chemistry, Tandem mass spectrometry, Uranyl, 01 natural sciences, Dissociation (chemistry), 0104 chemical sciences, Adduct, chemistry.chemical_compound, Physical chemistry, Density functional theory, Reactivity (chemistry), Spectroscopy

Abstract

Electrospray ionization (ESI) can produce a wide range of gas-phase uranyl (UO2 2+ ) complexes for tandem mass spectrometry studies of intrinsic structure and reactivity. We describe here the formation and collision-induced dissociation (CID) of [UO2 (NO3 )3 ]- and [UO2 (NO3 )2 (O2 )]- . Multiple-stage CID experiments reveal that the complexes dissociate in reactions that involve elimination of O2 , NO2 , or NO3 , and subsequent reactions of interesting uranyl-oxo product ions with (neutral) H2 O and/or O2 were investigated. Density functional theory (DFT) calculations reproduce experimental results and show that dissociation of nitrate ligands, with ejection of neutral NO2 , is favored for both [UO2 (NO3 )3 ]- and [UO2 (NO3 )2 (O2 )]- . DFT calculations also suggest that H2 O adducts to products such as [UO2 (O)(NO3 )]- spontaneously rearrange to create dihydroxides and that addition of O2 is favored over addition of H2 O to formally U(V) species.

Published

2021

5. Creation of [OUF]+ using gas-phase reactions of [UO2(C6F5)]+

Author

Anna Iacovino, Árpád Somogyi, Amanda R. Bubas, Evan Perez, Theodore A. Corcovilos, Luke J. Metzler, Susan Kline, Irena Tatosian, and Michael J. Van Stipdonk

Subjects

Decarboxylation, Ligand, Condensed Matter Physics, Medicinal chemistry, Dissociation (chemistry), Ion, Hydrolysis, chemistry.chemical_compound, chemistry, Reagent, Hydroxide, Ion trap, Physical and Theoretical Chemistry, Instrumentation, Spectroscopy

Abstract

While the strong axial U O bonds confer high stability and inertness to UO22+, it has been shown that the axial oxo ligands can be eliminated or replaced in the gas-phase using collision-induced dissociation (CID) reactions. In this study, CID of the pentafluorobenzoate precursor ion [UO2(O2C–C6F5)]+ was used to produce the organo-uranyl ion [UO2(C6F5)]+ by decarboxylation. Subsequent CID of [UO2(C6F5)]+ created [UO2(F)]+ by fluoride transfer and elimination of C6F4, rather than UO2+ by elimination of pentafluorophenyl radical (as has been observed for similar species). Moreover, upon reaction of [UO2(C6F5)]+ with H2O, apparent substitution of OH for F to create [UO3HC6F4]+ is favored over hydrolysis to produce [UO2(OH)]+ and (neutral) C6F5H. Subsequent CID of [UO3HC6F4]+ generates [UO2(F)]+ and [OUF]+. When [OUF]+ is isolated to react with H2O and O2 in the ion trap, the principal product ions observed are [UO2(F)]+ and [UO2(OH)]+. Experiments conducted with labeled reagent suggest that reaction with H218O leads to exchange of the oxo ligand and incorporation of the 18O label into [OUF]+ while reaction with O2 likely creates [UO2(F)]+. Formation of [UO2(OH)]+ from [OUF]+ is the result of a cascade of reactions, with initial formation of [UO2(F)]+ by reaction with O2, followed by hydrolysis to create the hydroxide species.

Published

2021

6. Measurement of the asymmetric UO22+ stretching frequency for [UVIO2(F)3]- using IRMPD spectroscopy

Author

Jonathan Martens, Jos Oomens, Theodore A. Corcovilos, Giel Berden, Amanda R. Bubas, Irena Tatosian, Michael J. Van Stipdonk, Connor Graca, Luke J. Metzler, and Molecular Spectroscopy (HIMS, FNWI)

Subjects

FELIX Molecular Structure and Dynamics, Infrared, Chemistry, 010401 analytical chemistry, Photodissociation, Analytical chemistry, 010402 general chemistry, Condensed Matter Physics, Uranyl, 01 natural sciences, 0104 chemical sciences, chemistry.chemical_compound, Density functional theory, Infrared multiphoton dissociation, Physical and Theoretical Chemistry, Spectroscopy, Instrumentation

Abstract

In a previous study [Int. J. Mass Spectrom. 2010; 297: 67–75], the asymmetric O=U=O stretch (ν3) was measured for anionic uranyl complexes with composition [UO2(X)3]-, X = Cl-, Br- and I-. Within this group of complexes, the ν3 frequency red-shifts following the trend I > Br > Cl, suggesting concomitant weakening of the U=O bonds. However, a value for [UO2(F)3]- was not measured, which prevented a comprehensive comparison of measured ν3 positions to computed frequencies from density functional theory (DFT) calculations. Because the shift in ν3 is predicted to be most dramatic when X = F, we revisited these species using infrared multiple-photon photodissociation spectroscopy. As in our earlier study, a modest red-shift to the ν3 vibration of ∼ 6 cm-1 was observed for X = I-, Br-, and Cl-, and the position of the frequency follows the trend I- > Br- > Cl-. The value measured for [UO2(F)3]- is ∼43 cm-1 lower than the one measured for [UO2(Cl)3]-. Overall, the trend with respect to ν3 position is reproduced well by computed frequencies from DFT.

Published

2019