Excited-State N Atoms Transform Aromatic Hydrocarbons into <i>N</i>-Heterocycles in Low-Temperature Plasmas

Begley, Alina; Shuman, Nicholas S.; Long, Bryan A.; Kämpf, Robin; Gyr, Luzia; Viggiano, Albert A.; Zenobi, Renato

doi:10.1021/acs.jpca.1c10657

Cited by 5 publications

(9 citation statements)

References 49 publications

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“…The discovery of new N 2 transitions forbidden by the spin-selection rule and induced by SOC perturbation is an important part of optical nitrogen monitoring at different altitudes. The intensity origin of the known emission bands that are forbidden by the electric dipole selection rules is also an important task of N 2 spectroscopy ( Deslandres, 1902 ; Wilkinson and Mulliken, 1959 ; Brown and Winkle, 1970 ; Lofthus and Krupenie, 1977 ; Werner et al, 1984 ; Partridge et al, 1988 ; Piper, 1993 ; Minaev et al, 1995 ; Lewis et al, 2008 ; Ndome et al, 2008 ; Hochlaf et al, 2010a ; Ni et al, 2017 ; Begley et al, 2022 ). This work presents multi-reference configuration interaction (MRCI) calculations of the highly excited states of the nitrogen molecule and an explanation of the intensity origin of several forbidden optical transitions.…”

Section: Energy Harvesting By Triplet States Of Nitrogenmentioning

confidence: 99%

“…In contrast, the ground state of the nitrogen molecule possesses zero spin and several high-energy triplet excited states with deep potential wells. The lowest of them,

, can harvest a stock of 6.22 eV energy, being a strongly metastable triplet state with a relatively long radiative lifetime (τ r ) of 2 s ( Brown and Winkle, 1970 ; Minaev et al, 1995 ; Begley et al, 2022 ). Accounting for the short UV wavelength of the

transition, this τ r value is indeed unusually large.…”

Section: Introductionmentioning

confidence: 99%

“…N 2 is a very stable and inert molecule in the ground state

with high dissociation energy (D e = 9.76 eV). At the same time, N 2 possesses a variety of quite stable valence excitations of the π u –π g and 3σ g –π g types; these excited states have large D e values (around 4–6 eV) and are mostly metastable since their emission to the ground state is strictly forbidden by the electric dipole selection rules ( Wilkinson and Mulliken, 1959 ; Brown and Winkle, 1970 ; Begley et al, 2022 ; Minaev et al, 1995 ; Lewis et al, 2008 ; Lofthus. and Krupenie, 1977 ).…”

Section: Introductionmentioning

confidence: 99%

“…In gaseous electric discharges, when a molecule is irradiated by an electron flux, N 2 dissociates into the ground state N ( 4 S) atoms; they can recombine forming the lowest singlet (X 1 Σ g + ), triplet (A 3 Σ u + ), and quintet (A′ 5 Σ g – ) basic states. The last two, shown in Figure 1 , are involved in the so-called active nitrogen phenomenon detected by the characteristic “yellow afterglow” ( Brown and Winkle, 1970 ; Begley et al, 2022 ). Its study together with aurora borealis involves a large number of metastable states and forbidden transitions in the N 2 spectrum ( Figure 2 ).…”

Section: Introductionmentioning

confidence: 99%

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Triplet state harvesting and search for forbidden transition intensity in the nitrogen molecule

et al. 2022

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Triplet excited states of the N2 molecule play an important role in electric discharges through air or liquid nitrogen accompanied by various afterglows. In the rarefied upper atmosphere, they produce aurora borealis and participate in other energy-transfer processes connected with atmospheric photochemistry and nightglow. In this work, we present spin–orbit coupling calculations of the intensity of various forbidden transitions, including the prediction of the electric dipole transition moment of the new 13Σg−← A3Σu+ band, which is strongly prohibited by the (+|−) selection rule, the new spin-induced magnetic B′3Σu−← A3Σu+ transition, magnetic and electric quadrupole transitions for the B3Πg← X1Σg+ Wilkinson band, and the Lyman–Birge–Hopfield a1Πg ← X1Σg transition. Also, two other far-UV singlet–singlet quadrupole transitions are calculated for the first time, namely, the Dressler–Lutz a"1Σg+–X1Σg+ and the less studied z1Δg–X1Σg+ weak transitions.

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Section: Energy Harvesting By Triplet States Of Nitrogenmentioning

confidence: 99%

“…In contrast, the ground state of the nitrogen molecule possesses zero spin and several high-energy triplet excited states with deep potential wells. The lowest of them,

transition, this τ r value is indeed unusually large.…”

Section: Introductionmentioning

confidence: 99%

“…N 2 is a very stable and inert molecule in the ground state

Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

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Triplet state harvesting and search for forbidden transition intensity in the nitrogen molecule

et al. 2022

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“…While these studies focus on generating intact molecular ions, N‐addition product ions [M + N] + of alkylbenzenes have been reported in APCI 24 and for volatile saturated hydrocarbons in electric fields 25 . Previously, we investigated the formation of these products for aromatic hydrocarbons in a DBDI and found that excited state N‐atoms N( 2 P) can react with aromatic hydrocarbon cations [M] •+ in the source to form either N‐addition or ‐replacement products 26 . We hypothesized that the reaction could be used to discriminate alkylbenzene isomers based on steric hindrance of the isomers, without the addition of special reagents.…”

Section: Introductionmentioning

confidence: 99%

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

2023

Self Cite

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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‐doping graphene at ambient conditions with N₂‐DBD‐plasma and the role of neutral species

Begley,

Bartolomeo,

Abbott

et al. 2023

Plasma Processes & Polymers

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We doped nitrogen into monolayer graphene using reactive nitrogen species from a dielectric barrier discharge (DBD). After 30 s of treatment, the graphene monolayer had a moderate degree of damage (ID/IG = 1.2) and an increase in the N‐atom (pyrrolic) and O‐atom (mixed) content. During long treatment times (20 min), the treated area increased radially and the graphene was destroyed. Overall, the N‐atom content increased with increasing operating voltage of the DBD source. When the graphene was treated with only neutral reactive nitrogen species, the N‐atom content and type remained unchanged. Therefore, we hypothesize that the primary reactive species resulting in pyrrolic N‐doping from the DBD are neutrals such as N(4S) and possibly N(2P).

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

Cited by 5 publications

References 49 publications

Triplet state harvesting and search for forbidden transition intensity in the nitrogen molecule

Triplet state harvesting and search for forbidden transition intensity in the nitrogen molecule

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

Nitrogen‐doping graphene at ambient conditions with N₂‐DBD‐plasma and the role of neutral species

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

Cited by 5 publications

References 49 publications

Triplet state harvesting and search for forbidden transition intensity in the nitrogen molecule

Triplet state harvesting and search for forbidden transition intensity in the nitrogen molecule

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

Nitrogen‐doping graphene at ambient conditions with N2‐DBD‐plasma and the role of neutral species

Contact Info

Product

Resources

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Nitrogen‐doping graphene at ambient conditions with N₂‐DBD‐plasma and the role of neutral species