Aqueous Microdroplets Capture Elusive Carbocations

Kumar, Anubhav; Mondal, Supratim; Banerjee, Shibdas

doi:10.1021/jacs.0c12512

Cited by 36 publications

(54 citation statements)

References 42 publications

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“…Spectroscopic information coupled with MS measurements would be very valuable to identify the electronic and geometric structures of chemical intermediates in solution. Ambient ionization techniques such as ESI and desorption ESI (DESI) have been extensively used for chemical reactions characteristic of charged droplets or as probes for chemical reactions in bulk phases. ,,, Hence, the application of new spectroscopic techniques to MS measurements will open a new area of growing interest for reaction chemistry and photochemistry.…”

Section: Discussionmentioning

confidence: 99%

“…Chemical intermediates are generally not very abundant in solution because of their short lifetimes, which prevents their selective detection. In the last three decades, extensive efforts have been devoted to detecting chemical intermediates in solution using mass spectrometric (MS) techniques. − MS studies determined the molecular weight or atomic constituents of the species, but predictions by quantum chemical calculations or chemical intuition were needed to estimate the electronic and geometric structures of the intermediates. Roithová et al reported pioneering studies of photochemical intermediates in the gas phase using ion spectroscopy to examine the reaction mechanism in solution. , They used ion-mobility mass spectrometry, infrared photodissociation spectroscopy, and visible photodissociation spectroscopy to identify photochemical intermediates produced in solution.…”

Section: Introductionmentioning

confidence: 99%

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Structural Investigation of Photochemical Intermediates in Solution by Cold UV Spectroscopy in the Gas Phase: Photosubstitution of Dicyanobenzenes by Allylsilanes

et al. 2021

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Electrospray ion sources with an in-line quartz cell were constructed to produce photochemical intermediates in solution. These ion sources can detect photochemical intermediates having lifetimes longer than a few seconds. Intermediates formed by photosubstitution of 1,4-dicyanobenzene (DCB) by allyltrimethylsilane (AMS) in acetonitrile using a Xe lamp were injected into the mass spectrometer. The cationic intermediate (C 11 H 10 N 2 •H + ) was observed at m/z = 171, but no anionic intermediate was found, although C 11 H 9 N 2 − was expected based on prior studies. Theoretical studies suggested that C 11 H 9 N 2 − was simultaneously converted to neutral C 11 H 10 N 2 and cationic C 11 H 10 N 2 •H + species, which can be stable intermediates in the photosubstitution reaction. The UV photodissociation (UVPD) spectrum of C 11 H 10 N 2 •H + under cold (∼10 K) gas-phase conditions determined the conformation of the C 11 H 10 N 2 unit of the C 11 H 10 N 2 •H + cation. This report demonstrates that cold gas-phase UV spectroscopy is a prospectively powerful tool for investigation of the electronic and geometric structures of photochemical intermediates produced in solution.

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Section: Discussionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Structural Investigation of Photochemical Intermediates in Solution by Cold UV Spectroscopy in the Gas Phase: Photosubstitution of Dicyanobenzenes by Allylsilanes

et al. 2021

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“…Chemical intermediates are generally not very abundant in solution due to their short lifetimes, which prevents their selective detection in the solution. In the last three decades, several mass spectrometric (MS) techniques have been extensively applied to the chemical intermediates produced in solutions. − These studies could determine the molecular weight or the atomic constituents of the species; however, spectroscopic investigations are required to predict the structure of the intermediates. Recently, Mayer and Asmis reported the gas-phase IR spectroscopy of chemical intermediates produced using a microfluidic chip-reactor …”

Section: Introductionmentioning

confidence: 99%

Gas-Phase UV Spectroscopy of Chemical Intermediates Produced in Solution: Oxidation Reactions of Phenylhydrazines by DDQ

et al. 2021

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In this study, we demonstrated cold gas-phase spectroscopy of chemical intermediates produced in solution. Herein, we combined an electrospray ion source with a Tshaped solution mixer for introducing chemical intermediates in solution into the gas phase. Specifically, the oxidation reaction of 2-(4-nitrophenyl)hydrazinecarboxaldehyde (NHCA) by 2,3dichloro-5,6-dicyano-p-benzoquinone (DDQ) was initiated by mixing the methanol solutions of NHCA and DDQ in the T-shaped mixer, and the chemical species were injected into the vacuum apparatus for ultraviolet photodissociation (UVPD) spectroscopy. A cationic intermediate was strongly observed at m/z 150 in the mass spectrum, and the UVPD spectrum was observed under cold (∼10 K) gas-phase conditions. The UVPD spectrum showed a strong, broad absorption at ∼38,000 cm −1 , accompanied by a relatively weak component at ∼34,000 cm −1 . These spectral patterns can be ascribed to a diazonium cation intermediate, whose existence has been predicted in a previous study. This report indicates that cold gas-phase UV spectroscopy can be a useful method for identifying the structure of chemical intermediates produced in solution.

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“…The droplet evolution on a millisecond time scale desorbs reactive (metal-free) carbanions to the gas phase for mass spectrometric detection, allowing real-time monitoring of the formation of such reactive species as intermediates. This work is influenced by our recent study that electrohydrodynamically generated water microdroplets can intercept, stabilize, and transfer very effectively reactive carbocations from a reaction medium to the gas phase for mass spectrometric detection. , However, this report presents a strikingly different result: unlike carbocations, carbanions better survive in aqueous microdroplets containing methanol or acetonitrile. In addition to the carbanion stability in microdroplets, we also investigated the possible factors that may cause this difference.…”

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confidence: 98%

Capturing Reactive Carbanions by Microdroplets

et al. 2022

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Carbanions appear in many organic or biological reactions as fleeting intermediates, prohibiting direct observation or spectroscopic measurement. An aqueous environment is known to rapidly annihilate a carbanion species, reducing its lifetime to as short as picoseconds. We report that aqueous microdroplets can capture and stabilize reactive carbanion intermediates isolated from four classic organic reactions, aldol and Knoevenagel condensations, alkyne alkylation, and the Reimer–Tiemann reaction, enabling the detection of their carbanion intermediates by desorption electrospray ionization mass spectrometry. This is accomplished in real time of the reaction, allowing new insights into reaction mechanisms to be obtained. The efficacy of microdroplets in capturing such elusive species was examined by varying the solvent and the microdroplet negative charge density. We observed that microdroplets composed of water–methanol outperform other solvents, such as pure water, in capturing carbanions, which is in contrast to the earlier report that presented the highest performance of pure water microdroplets in capturing carbocations. We offer some mechanistic insights to explain the discriminatory behavior of these two oppositely charged species in microdroplets.

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Aqueous Microdroplets Capture Elusive Carbocations

Cited by 36 publications

References 42 publications

Structural Investigation of Photochemical Intermediates in Solution by Cold UV Spectroscopy in the Gas Phase: Photosubstitution of Dicyanobenzenes by Allylsilanes

Structural Investigation of Photochemical Intermediates in Solution by Cold UV Spectroscopy in the Gas Phase: Photosubstitution of Dicyanobenzenes by Allylsilanes

Gas-Phase UV Spectroscopy of Chemical Intermediates Produced in Solution: Oxidation Reactions of Phenylhydrazines by DDQ

Capturing Reactive Carbanions by Microdroplets

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