The N(4S) + N2O(X̃1∑) reaction

Fernandez, Abel; Fontijn, Arthur

doi:10.1002/kin.1032

Cited by 3 publications

(2 citation statements)

References 11 publications

(12 reference statements)

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“…At last, in order to verify this work, the rate constants by this calculation were compared with Femandes' experiment data. [ 65 ] It can be seen that the references and the calculations were more and more close as the temperature increased.…”

Section: Resultsmentioning

confidence: 70%

Theoretical calculations and anahrmonic effect analysis for the conversion of nitrogen radical in burning reaction

Xia

Chen

et al. 2021

J Chinese Chemical Soc

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The purpose of this research is that clearly comprehends the conversion and reaction mechanism of N radical in burning reaction. The harmonic and anharmonic rate constants of the related reactions were calculated by the transition state (TS) theory and Yao and Lin (YL) method. And the kinetic and thermodynamic parameters considering anharmonic and harmonic factor were fitted respectively. In conclusion, the anharmonic effect cannot be ignored on the reaction process of N radical conversion. Besides, the simulation by CHEMKIN will be carried out by the fitted results in the future work.Therefore, the calculation can provide theoretical basis for the further research of the N-related reactions, such as on the aspect of the removal of NOx.

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Section: Resultsmentioning

confidence: 70%

Theoretical calculations and anahrmonic effect analysis for the conversion of nitrogen radical in burning reaction

Xia

Chen

et al. 2021

J Chinese Chemical Soc

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“…While the neutral–neutral reactions of C and N atoms with NO molecules are reasonably well characterized at low temperature through several experimental and theoretical studies − (the reaction between ground state atomic oxygen and nitric oxide occurs through three body association, which will be negligible at the densities of interstellar clouds), there are very few studies of gas-phase N 2 O reactions at interstellar temperatures. In terms of its reactivity toward atomic radicals, N 2 O is not expected to react with N or O atoms at low temperature (the N + N 2 O reaction is spin forbidden while the O + N 2 O reaction is characterized by a large activation barrier). In contrast, the reactivity of atomic carbon toward N 2 O has been studied at room temperature by the Husain group , using the flash photolysis of carbon suboxide as a source of ground state atomic carbon with these atoms being detected by resonance absorption around 166 nm.…”

Section: Introductionmentioning

confidence: 99%

An Experimental and Theoretical Investigation of the Gas-Phase C(³P) + N₂O Reaction. Low Temperature Rate Constants and Astrochemical Implications

et al. 2022

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The reaction between atomic carbon in its ground electronic state, C( 3 P), and nitrous oxide, N2O, has been studied below room temperature due to its potential importance for astrochemistry, with both species considered to be present at high abundance levels in a range of interstellar environments. On the experimental side, we measured rate constants for this reaction over the 50-296 K range using a continuous supersonic flow reactor. C( 3 P) atoms were generated by the pulsed photolysis of carbon tetrabromide at 266 nm and were detected by pulsed laser induced fluorescence at 115.8 nm. Additional measurements allowing the major product channels to be elucidated were also performed. On the theoretical side, statistical rate theory was used to calculate low temperature rate constants. These calculations employed the results of new electronic structure calculations of the 3 A² potential energy surface of CNNO and provided a basis to extrapolate the measured rate constants to lower temperatures and pressures. The rate constant was found to increase monotonically as the temperature falls (𝑘 !( ! #)%& " ' (296 K) = (3.4 ± 0.3) ´ 10 -11 cm 3 s -1 ), reaching a value of 𝑘 !( ! #)%& " ' (50 K) = (7.9 ± 0.8) ´ 10 -11 cm 3 s -1 at 50 K. As current astrochemical models do not include the C + N2O reaction, we tested the influence of this process on interstellar N2O and other related species using a gas-grain model of dense interstellar clouds. These simulations predict that N2O abundances decrease significantly at intermediate times (10 3 -10 5 years) when gas-phase C( 3 P) abundances are high.

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Nitrous Oxide: Electron Attachment and Possible Scenario for Its Reaction with ns Metal Atoms

Tishchenko¹,

Kryachko²,

Nguyen³

2003

Fundamental World of Quantum Chemistry

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The N(⁴S) + N₂O(X̃¹∑) reaction

Abstract: The title reaction, which is spin-forbidden for production,has been studied from 960 to 1130 K in a high-temperature photochemistry reactor. No re-

Cited by 3 publications

References 11 publications

Theoretical calculations and anahrmonic effect analysis for the conversion of nitrogen radical in burning reaction

Theoretical calculations and anahrmonic effect analysis for the conversion of nitrogen radical in burning reaction

An Experimental and Theoretical Investigation of the Gas-Phase C(³P) + N₂O Reaction. Low Temperature Rate Constants and Astrochemical Implications

Nitrous Oxide: Electron Attachment and Possible Scenario for Its Reaction with ns Metal Atoms

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The N(4S) + N2O(X̃1∑) reaction

Abstract: The title reaction, which is spin-forbidden for production,has been studied from 960 to 1130 K in a high-temperature photochemistry reactor. No re-

Cited by 3 publications

References 11 publications

Theoretical calculations and anahrmonic effect analysis for the conversion of nitrogen radical in burning reaction

Theoretical calculations and anahrmonic effect analysis for the conversion of nitrogen radical in burning reaction

An Experimental and Theoretical Investigation of the Gas-Phase C(3P) + N2O Reaction. Low Temperature Rate Constants and Astrochemical Implications

Nitrous Oxide: Electron Attachment and Possible Scenario for Its Reaction with ns Metal Atoms

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Product

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The N(⁴S) + N₂O(X̃¹∑) reaction

An Experimental and Theoretical Investigation of the Gas-Phase C(³P) + N₂O Reaction. Low Temperature Rate Constants and Astrochemical Implications