Comparison of gas‐phase basicities and ion–molecule reactions of aminobenzoic acids

Tang, Ming Lee; Isbell, John; Hodges, Bradley; Brodbelt, Jennifer S.

doi:10.1002/jms.1190300707

Cited by 22 publications

(29 citation statements)

References 30 publications

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“…[1][2][3][4] In contrast, the favored protonation site for this molecule in the gas phase is the carbonyl oxygen. [3][4][5][6][7] However, infrared multiple photon dissociation and other studies have shown that both protomers can coexist under certain experimental conditions. [3][4][5] For example, when protonated p-ABA is generated from a solution by electrospray ionization (ESI), the relative abundance of the 2 protomers depends primarily on the composition of the spray solvent.…”

Section: Introductionmentioning

confidence: 98%

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Transformation of the gas‐phase favored O‐protomer of p‐aminobenzoic acid to its unfavored N‐protomer by ion activation in the presence of water vapor: An ion‐mobility mass spectrometry study

Xia

Attygalle

2018

J Mass Spectrom

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An ion-mobility mass spectrometry study showed that the preferred O-protonated form of p-aminobenzoic in the gas phase can be converted to the thermodynamically less favored N-protomer by in-source collision-induced ion activation during the ion transfer process from the atmospheric region to the first vacuum region if the humidity is high in the ion source. Upon the addition of water vapor to the nitrogen gas used to promote the solid analyte to the gas phase under helium-plasma ionization conditions, the intensity of the ion-mobility arrival-time peak for the N-protomer increased dramatically. Evidently, the ion-activation process in the first vacuum region is able to provide the energy required to surmount the barrier to isomerize the O-protomer to the more energetic N-protomer. The transfer of the proton attached to the carbonyl oxygen atom of the O-protomer to the amino group takes place by a water-bridge mechanism. Apparently, the postionization transformations that take place during the transmission of ions from the atmospheric-pressure ion source to the detector, via different physical compartments of low to high vacuum, play an eminent role in determining the population ratios eventually manifested at the detector.

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Section: Introductionmentioning

confidence: 98%

“…In solution, p ‐ABA protonates preferentially at the amino group (Scheme ) . In contrast, the favored protonation site for this molecule in the gas phase is the carbonyl oxygen . However, infrared multiple photon dissociation and other studies have shown that both protomers can coexist under certain experimental conditions .…”

Section: Introductionmentioning

confidence: 99%

Transformation of the gas‐phase favored O‐protomer of p‐aminobenzoic acid to its unfavored N‐protomer by ion activation in the presence of water vapor: An ion‐mobility mass spectrometry study

Xia

Attygalle

2018

J Mass Spectrom

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“…16 Tang et al have examined the gas-phase basicity of the three isomers of amino benzoic acids in a quadrupole ion trap. 17 Mass selective gas-phase infrared ͑IR͒ spectroscopy of PABA has been studied by Putter, von Helden, and Meijer via infrared and vacuum ultraviolet double resonance ionization. 18 In a very recent study, Compagnon et al have measured the permanent electric dipole moment of isolated PABA in the ground state by coupling a matrix-assisted laser desorption source to an electric beam deflection setup.…”

Section: Introductionmentioning

confidence: 99%

Zero kinetic energy photoelectron spectroscopy of p-amino benzoic acid

Kong

2004

The Journal of Chemical Physics

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We report studies of supersonically cooled p-amino benzoic acid using one-color resonantly enhanced multiphoton ionization and two-color zero kinetic energy (ZEKE) photoelectron spectroscopy. With the aid of ab initio and density functional calculations, vibrational modes of the first electronically excited state S(1) of the neutral species and those of the cation have been assigned, and the adiabatic ionization potential has been determined to be 64 540+/-5 cm(-1). A common pattern involving the activation of five vibrational modes of the cation is recognizable among all the ZEKE spectra. A propensity of Deltav=0, where v is the vibrational quantum number of the intermediate vibronic state from S(1), is confirmed, and the origin of this behavior is discussed in the context of electron back donation from the two substituents in the excited state and in the cationic state. A puzzling observation is the doublet splitting of 37 cm(-1) in the ZEKE spectrum obtained via the inversion mode of the S(1) state. This splitting cannot be explained from our density functional calculations.

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“…SIMR leading to the formation of methyne addition reactions in an ITMS has been investigated previously 6–9. Brodbelt and co‐workers examined methyne addition reactions by dimethyl ether (DME) CI for many compounds using an ITMS 10–26. The purpose of this paper is to describe the phenomenon when CAD is performed on the methyne adduct ions produced from both SIMR or CI, using both external and internal source ITMS instruments, where the SIMR can occur and lead to the formation of the protonated molecules or adduct ions.…”

Section: Introductionmentioning

confidence: 99%

Observation of self‐ion–molecule reactions during collisionally activated dissociation in an ion‐trap mass spectrometer

Chen

2004

J. Mass Spectrom.

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This paper describes the formation of protonated molecules ([M + H]+) and adduct ions by self-ion-molecule reactions (SIMR) during collisionally activated decomposition (CAD) of methyne addition ions ([M + CH]+) produced from chemical ionization (CI) or SIMR in both an external and internal source ion-trap mass spectrometer (ITMS). The CAD results for the methyne addition ions of dopamine produced from both SIMR and dimethyl ether CI undertaken in the external and internal source ITMS were compared in order to prove the occurrence of SIMR during CAD processes. Compared with the external source ITMS, the internal source ITMS is much more easily applicable to this type of reaction owing to the large population of neutral analytes present in the trap.

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Comparison of gas‐phase basicities and ion–molecule reactions of aminobenzoic acids

Cited by 22 publications

References 30 publications

Transformation of the gas‐phase favored O‐protomer of p‐aminobenzoic acid to its unfavored N‐protomer by ion activation in the presence of water vapor: An ion‐mobility mass spectrometry study

Transformation of the gas‐phase favored O‐protomer of p‐aminobenzoic acid to its unfavored N‐protomer by ion activation in the presence of water vapor: An ion‐mobility mass spectrometry study

Zero kinetic energy photoelectron spectroscopy of p-amino benzoic acid

Observation of self‐ion–molecule reactions during collisionally activated dissociation in an ion‐trap mass spectrometer

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