Nitrogen‐containing organic products from the treatment of liquid toluene with plasma‐activated N<sub>2</sub> gas

Hosseini, Hamideh; Saleem, Mubbshir; Marotta, Ester; Paradisi, Cristina

doi:10.1002/ppap.202100012

Cited by 10 publications

(11 citation statements)

References 24 publications

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“…21–26 Beyond plasma medicine, the effect of NTP treatment on organic molecules has also been extensively studied for other applications, in particular for the purpose of wastewater decontamination from persistent organic pollutants and recently new perspectives have been explored to synthesize highly valuable chemicals in a cheap and green way. 27…”

Section: Introductionmentioning

confidence: 99%

“…[21][22][23][24][25][26] Beyond plasma medicine, the effect of NTP treatment on organic molecules has also been extensively studied for other applications, in particular for the purpose of wastewater decontamination from persistent organic pollutants and recently new perspectives have been explored to synthesize highly valuable chemicals in a cheap and green way. 27 The use of biopolymers, especially of those able to form hydrogels, has been very limited in the field of plasma medicine. The two main aims have been the use of hydrogels to mimic tissues for studies related to RONS penetration and as vehicles for storage and local delivery of RONS.…”

Section: Introductionmentioning

confidence: 99%

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Does non-thermal plasma modify biopolymers in solution? A chemical and mechanistic study for alginate

et al. 2023

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Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Does non-thermal plasma modify biopolymers in solution? A chemical and mechanistic study for alginate

et al. 2023

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“…Understanding chemical pathways for the formation of N -heterocycles can give insights into their origin in primordial earth and extraterrestrial environments. A new pathway for the formation of N -heterocycles has recently been reported in a nitrogen-based low-temperature plasma by direct substitution of carbon with nitrogen in aromatic hydrocarbons. , However, the mechanism by which a stable aromatic ring may be broken and a carbon atom replaced with a nitrogen atom from elemental N 2 has been unclear because the reactive species in low-temperature plasmas are only partly characterized and the reaction mechanisms are not fully understood. − …”

Section: Introductionmentioning

confidence: 99%

“…A new pathway for the formation of N-heterocycles has recently been reported in a nitrogen-based low-temperature plasma by direct substitution of carbon with nitrogen in aromatic hydrocarbons. 1,2 However, the mechanism by which a stable aromatic ring may be broken and a carbon atom replaced with a nitrogen atom from elemental N 2 has been unclear because the reactive species in low-temperature plasmas are only partly characterized and the reaction mechanisms are not fully understood. 3−6 Plasmas are ionized gases and considered the fourth state of matter; they are highly energetic, reactive, and responsive to electric and magnetic fields.…”

Section: Introductionmentioning

confidence: 99%

Excited-State N Atoms Transform Aromatic Hydrocarbons into N-Heterocycles in Low-Temperature Plasmas

et al. 2022

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The direct formation of N-heterocycles from aromatic hydrocarbons has been observed in nitrogen-based lowtemperature plasmas; the mechanism of this unusual nitrogenfixation reaction is the topic of this paper. We used homologous aromatic compounds to study their reaction with reactive nitrogen species (RNS) in a dielectric barrier discharge ionization (DBDI) source. Toluene (C 7 H 8 ) served as a model compound to study the reaction in detail, which leads to the formation of two major products at "high" plasma voltage: a nitrogen-replacement product yielding protonated methylpyridine (C 6 H 8 N + ) and a protonated nitrogen-addition (C 7 H 8 N + ) product. We complemented those studies by a series of experiments probing the potential mechanism. Using a series of selected-ion flow tube experiments, we found that N + , N 2 + , and N 4 + react with toluene to form a small abundance of the N-addition product, while N( 4 S) reacted with toluene cations to form a fragment ion. We created a model for the RNS in the plasma using variable electron and neutral density attachment mass spectrometry in a flowing afterglow Langmuir probe apparatus. These experiments suggested that excited-state nitrogen atoms could be responsible for the N-replacement product. Density functional theory calculations confirmed that the reaction of excitedstate nitrogen N( 2 P) and N( 2 D) with toluene ions can directly form protonated methylpyridine, ejecting a carbon atom from the aromatic ring. N( 2 P) is responsible for this reaction in our DBDI source as it has a sufficient lifetime in the plasma and was detected by optical emission spectroscopy measurements, showing an increasing intensity of N( 2 P) with increasing voltage.

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“…Near the ignition voltage of the plasma, at 2.4 kV pp , molecular ions [M] +• are formed by reaction with N At an increased operating voltage of 3.4 kV pp (Figure 2B), nitrogen addition [M + N] + and replacement [M-C + N] + products are formed, because N-atom density35 and the population of electronically excited state N-atoms36,37 increase exponentially with energy in filamentary DBDs. The replacement product [M-C + N] + has been previously reported in DBDIs as corresponding to protonated N-heterocycle,38,39 whereas the nitrogen addition [M + N] + product may correspond to a protonated amine, N-atom adduct, or N-azepine.…”

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confidence: 99%

Discriminating alkylbenzene isomers with tandem mass spectrometry using a dielectric barrier discharge ionization source

2023

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Soft ambient ionization sources generate reactive species that interact with analyte molecules to form intact molecular ions, which allows rapid, sensitive, and direct identification of the molecular mass. We used a dielectric barrier discharge ionization (DBDI) source with nitrogen at atmospheric pressure to detect alkylated aromatic hydrocarbon isomers (C 8 H 10 or C 9 H 12 ). Intact molecular ions [M] •+ were detected at 2.4 kV pp , but at increased voltage (3.4 kV pp ), [M + N] + ions were formed, which could be used to differentiate regioisomers by collision-induced dissociation (CID). At 2.4 kV pp , alkylbenzene isomers with different alkyl-substituents could be identified by additional product ions: ethylbenzene and -toluene formed [M-2H] + , isopropylbenzene formed abundant [M-H] + , and propylbenzene formed abundant C 7 H 7 + . At an operating voltage of 3.4 kV pp , fragmentation of [M + N] + by CID led to neutral loss of HCN and CH 3 CN, which corresponded to steric hindrance for excited state N-atoms approaching the aromatic ring (C-H). The ratio of HCN to CH 3 N loss (interday relative standard deviation [RSD] < 20%) was distinct for ethylbenzene and ethyltoluene isomers. The greater the number of alkyl-substituents (C-CH 3 ) and the more sterically hindered (meta > para > ortho) the aromatic core, the greater the loss of CH 3 CN relative to HCN was.

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Nitrogen‐containing organic products from the treatment of liquid toluene with plasma‐activated N₂ gas

Cited by 10 publications

References 24 publications

Does non-thermal plasma modify biopolymers in solution? A chemical and mechanistic study for alginate

Does non-thermal plasma modify biopolymers in solution? A chemical and mechanistic study for alginate

Excited-State N Atoms Transform Aromatic Hydrocarbons into N-Heterocycles in Low-Temperature Plasmas

Discriminating alkylbenzene isomers with tandem mass spectrometry using a dielectric barrier discharge ionization source

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Nitrogen‐containing organic products from the treatment of liquid toluene with plasma‐activated N2 gas

Cited by 10 publications

References 24 publications

Does non-thermal plasma modify biopolymers in solution? A chemical and mechanistic study for alginate

Does non-thermal plasma modify biopolymers in solution? A chemical and mechanistic study for alginate

Excited-State N Atoms Transform Aromatic Hydrocarbons into N-Heterocycles in Low-Temperature Plasmas

Discriminating alkylbenzene isomers with tandem mass spectrometry using a dielectric barrier discharge ionization source

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Nitrogen‐containing organic products from the treatment of liquid toluene with plasma‐activated N₂ gas