State-to-State Master Equation and Direct Molecular Simulation Study of Energy Transfer and Dissociation for the N<sub>2</sub>–N System

Macdonald, Robyn L.; Torres, Erik; Schwartzentruber, Thomas E.; Panesi, Marco

doi:10.1021/acs.jpca.0c04029

Cited by 24 publications

(14 citation statements)

References 80 publications

(175 reference statements)

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“…Figure compares the present dissociation rate coefficients with the existing data. ,,,,,− For both chemical systems, the QSS rate coefficients have slightly lower values than the equilibrium ones, which is consistent with the results obtained for the N 2 + N , and O 2 + O systems. For the N 2 + O system, the measured N 2 + N dissociation rate coefficients − are employed in the comparison due to the lack of experimental data for the N 2 + O system.…”

Section: Resultssupporting

confidence: 89%

“…The present calculations predict lower values than the measured ones for both QSS and equilibrium. Interestingly, the present QSS dissociation rate coefficients in N 2 + O interactions are close to those for N 2 + N. , This seems to confirm the possible similarity in physical behavior among different chemical systems that have been discussed in detail in Sections and 3.2. In Figure S8, the PES cuts for N 2 O and N 3 are provided around one of the local minima locations of N 2 O 3 A′.…”

Section: Resultssupporting

confidence: 85%

“…Comparisons of the dissociation rate coefficients with the existing experimental ,− and theoretical ,,,,, data: (a) N 2 + O → 2N + O and (b) NO + N → 2N + O.…”

Section: Resultsmentioning

confidence: 99%

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Rovibrational-Specific QCT and Master Equation Study on N₂(X¹Σ_g⁺) + O(³P) and NO(X²Π) + N(⁴S) Systems in High-Energy Collisions

Venturi

Sharma

et al. 2022

J. Phys. Chem. A

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This work presents a detailed investigation of the energy-transfer and dissociation mechanisms in N2(X1Σg +) + O(3P) and NO(X2Π) + N(4S) systems using rovibrational-specific quasiclassical trajectory (QCT) and master equation analyses. The complete set of state-to-state kinetic data, obtained via QCT, allows for an in-depth investigation of the Zel’dovich mechanism leading to the formation of NO molecules at microscopic and macroscopic scales. The master equation analysis demonstrates that the low-lying vibrational states of N2 and NO have dominant contributions to the NO formation and the corresponding extinction of N2 through the exchange process. For the considered temperature range, it is found that nearly 50% of the dissociation processes for N2 and NO molecules occur in the quasi-steady-state (QSS) regime, while for the Zel’dovich reaction, the distribution of the reactants does not reach the QSS conditions. Furthermore, using the QSS approximation to model the Zel’dovich mechanism leads to overestimating NO production by more than a factor of 4 in the high-temperature range. The breakdown of this well-known approximation has profound consequences for the approaches that heavily rely on the validity of QSS assumption in hypersonic applications. Finally, the investigation of the rovibrational state population dynamics reveals substantial similarities among different chemical systems for the energy-transfer and the dissociation processes, providing promising physical foundations for the use of reduced-order strategies in other chemical systems without significant loss of accuracy.

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Section: Resultssupporting

confidence: 89%

Section: Resultssupporting

confidence: 85%

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Rovibrational-Specific QCT and Master Equation Study on N₂(X¹Σ_g⁺) + O(³P) and NO(X²Π) + N(⁴S) Systems in High-Energy Collisions

Venturi

Sharma

et al. 2022

J. Phys. Chem. A

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“…The present average rotational energy profile shows a larger discrepancy from the DMS result than the vibration during the non-equilibrium energy transfer. According to the previous studies by Venturi et al 2 and Macdonald et al 32 , it was demonstrated that the StS master equation approach yields very similar results with those from the DMS provided that the identical PES is adopted.…”

Section: Application To Combined O 3 +O 4 Systemmentioning

confidence: 92%

Rovibrational Internal Energy Transfer and Dissociation of High-Temperature Oxygen Mixture

Jo¹,

Venturi²,

Kim³

et al. 2022

Preprint

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“…Gordon & McBride (1994), the rates of vibrational excitation and dissociation have required complex measurements in shock tubes and other devices, although recent developments employing sophisticated theoretical methods to obtain the relevant data have been quite successful, see e.g. Macdonald et al (2020) and Chaudry et al (2020). Nevertheless, the uncertainties associated with dissociation rates remain so high that they are usually quoted as error margins of ±0.2 or so in the power of 10.…”

Section: Introductionmentioning

confidence: 99%

Computational analysis of experiments on shock detachment in hypersonic flow of nitrogen and carbon dioxide over a wedge

2022

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One of the most dramatic effects of vibrational and chemical non-equilibrium in hypersonic flows occurs in the bow-shock detachment process in flow over a wedge. This was shown theoretically and in reflected shock tunnel experiments by Hornung & Smith (J. Fluid Mech., vol. 93, 1979, pp. 225–239). In the present work, the effect is first demonstrated by computation of two-dimensional non-equilibrium flows. The effect of the finite transverse extent of the wedge is then studied by three-dimensional computations of non-relaxing flows. An analytical formula is obtained that gives the shock detachment distance of a finite wedge for ideal-gas and equilibrium flows. In the experiment, the finite transverse extent of the wedge competes with the non-equilibrium effects, as each introduces a new length scale. The carbon dioxide and nitrogen flows of the experiment are therefore computed in three dimensions and with two-temperature chemistry accounting for vibrational and chemical non-equilibrium. In the case of nitrogen flow, the agreement between experiment and computation is not good, the experimental detachment distance being larger. A number of possible reasons are quantitatively examined. A conclusive resolution of the discrepancy is considered to require a repeat of the experiment with more accurately characterized conditions. In the case of the carbon dioxide experiments, the computed results agree remarkably well with experiment. This is partially due to the fact that the condition is very close to equilibrium, where the sensitivity of the detachment process to relaxation effects is small. The analytical expression for the dimensionless detachment distance agrees very well with all the three-dimensional computations of non-relaxing flows.

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State-to-State Master Equation and Direct Molecular Simulation Study of Energy Transfer and Dissociation for the N₂–N System

Cited by 24 publications

References 80 publications

Rovibrational-Specific QCT and Master Equation Study on N₂(X¹Σ_g⁺) + O(³P) and NO(X²Π) + N(⁴S) Systems in High-Energy Collisions

Rovibrational-Specific QCT and Master Equation Study on N₂(X¹Σ_g⁺) + O(³P) and NO(X²Π) + N(⁴S) Systems in High-Energy Collisions

Rovibrational Internal Energy Transfer and Dissociation of High-Temperature Oxygen Mixture

Computational analysis of experiments on shock detachment in hypersonic flow of nitrogen and carbon dioxide over a wedge

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State-to-State Master Equation and Direct Molecular Simulation Study of Energy Transfer and Dissociation for the N2–N System

Cited by 24 publications

References 80 publications

Rovibrational-Specific QCT and Master Equation Study on N2(X1Σg+) + O(3P) and NO(X2Π) + N(4S) Systems in High-Energy Collisions

Rovibrational-Specific QCT and Master Equation Study on N2(X1Σg+) + O(3P) and NO(X2Π) + N(4S) Systems in High-Energy Collisions

Rovibrational Internal Energy Transfer and Dissociation of High-Temperature Oxygen Mixture

Computational analysis of experiments on shock detachment in hypersonic flow of nitrogen and carbon dioxide over a wedge

Contact Info

Product

Resources

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State-to-State Master Equation and Direct Molecular Simulation Study of Energy Transfer and Dissociation for the N₂–N System

Rovibrational-Specific QCT and Master Equation Study on N₂(X¹Σ_g⁺) + O(³P) and NO(X²Π) + N(⁴S) Systems in High-Energy Collisions

Rovibrational-Specific QCT and Master Equation Study on N₂(X¹Σ_g⁺) + O(³P) and NO(X²Π) + N(⁴S) Systems in High-Energy Collisions