Kinetic and Continuum Modeling of High-Temperature Air Relaxation

Gimelshein, S. F.; Wysong, Ingrid J.; Fangman, Alexander J.; Garbacz, Catarina; Morgado, Fábio; Кустова, Е. В.; Fossati, Marco; Hanquist, Kyle M.

doi:10.2514/1.t6462

Cited by 23 publications

(5 citation statements)

References 77 publications

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“…Analysis of the VV relaxation times computed using the empirical expression of Klomfass (5) showed excellent agreement with recent experimental data on O 2 -N 2 VV relaxation times [20] if the factor KV V cd was taken to be equal to 4 (in the original work of Klomfass it is equal to 1). Thus, in the present study, KV V cd was assumed to be uniformly distributed between 3 and 5, which corresponds to a 25% uncertainty in the VV relaxation times, this is comparable to the 30%-40% experimental uncertainty reported by Streicher et al [20].…”

Section: Parametrization Of Uncertainty Sourcessupporting

confidence: 73%

“…In shock tunnel facilities, such as the High Enthalpy Shock Tunnel Göttingen (HEG) [7], the flow is stagnated in order to achieve the required enthalpies; as it then expands through a nozzle section, thermochemical relaxation and subsequent freezing of the flow takes place, potentially leading to a chemically and vibrationally non-equilibrium flow at the nozzle exit [2]. The modeling of hypersonic flows is complicated by significant uncertainties in the data on the thermochemical relaxation rates, as well as the often significant impact on the choice of models to describe the relaxation processes [10,18,5,6].…”

Section: Introductionmentioning

confidence: 99%

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Uncertainty Quantification of Expanding High-Enthalpy Air Flows

Oblapenko,

Hannemann

2023

Notes on Numerical Fluid Mechanics and Multidisciplinary Design

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In the present work, we study the sensitivity of expanding hypersonic air flows in the HEG facility with respect to the thermochemical relaxation rates and reservoir conditions, along with the impact of uncertainties in the rates and reservoir conditions on uncertainties of the free-stream parameters. A simplified 1-D formulation of the flow equations is utilized to allow for simultaneous variation of a large number (10) of uncertain parameters. The simulation results show large uncertainties in the vibrational temperature of oxygen and molar fractions of oxygen-containing species, mainly due to uncertainties in the reservoir parameters and data on thermochemical relaxation rates of molecular oxygen.

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Section: Parametrization Of Uncertainty Sourcessupporting

confidence: 73%

Section: Introductionmentioning

confidence: 99%

Uncertainty Quantification of Expanding High-Enthalpy Air Flows

Oblapenko,

Hannemann

2023

Notes on Numerical Fluid Mechanics and Multidisciplinary Design

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“…The excited states PECs of the oxygen molecule are needed [20,21]. This study reports the PECs dissociating to the ground state atoms but the interaction of excited atoms poses a challenge which only recenltly have been addressed by one study [22].…”

Section: Introductionmentioning

confidence: 99%

Transport Cross Sections and Collision Integrals for O($$^{3}$$P)–O($$^{3}$$P) Interaction

Buchowiecki,

Szabó

2024

Plasma Chem Plasma Process

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New collision integrals and transport cross sections for O($$^{3}$$ 3 P)–O($$^{3}$$ 3 P) interaction are reported in the 300–30000 K range. Those values are based on a new set of potential energy curves (PECs) calculated with the multireference configuration interaction method. The results of the classical and semiclassical WKB (Wentzel–Kramers–Brillouin) methods are compared, excellent performance of the classical approach is shown (discrepancy much lower than 1% even at room temperature). In particular, the classical and WKB methods agree very well for the repulsive potentials effectively reducing overall uncertainty.

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“…Therefore physical-chemical processes can be strong enough to influence and even dominate the flow characters in the high-temperature region. The question and mechanism arouse many authors' interest [1][2][3][4][5] . The combination of kinetic energy and high speed is transformed into high air temperature and endothermal chemical processes (Figure 1), including the ionization and dissociation of atmospheric species in the high-temperature region.…”

Section: Introductionmentioning

confidence: 99%

Numerical Research for Hypersonic 3D Flow with High-Temperature Effect and Catalytic Conditions

Pan,

Sheng,

Liu

et al. 2023

J. Phys.: Conf. Ser.

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Investigating the high-temperature effect and catalytic condition with hypersonic flow numerical research was conducted by CFD methods. For comparison, flows were calculated by using a high-temperature nonequilibrium gas model and a calorically perfect gas model. All findings showed that high temperatures alter the flow properties considerably. The flow field structure, temperature distribution, pressure distribution, etc. were different from the calorically perfect gas assumption flow. All these differences would affect the aerodynamical force and aero heat of the fly vehicles with hypervelocity. Furthermore, all conditions of non-catalytic and catalytic effects were computed and compared. The flow with catalytic conditions produces more aero heats due to an exothermic recombination reaction near the wall. The methods and computations could be used for further engineering applications and hypersonic aerodynamical research.

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Kinetic and Continuum Modeling of High-Temperature Air Relaxation

Cited by 23 publications

References 77 publications

Uncertainty Quantification of Expanding High-Enthalpy Air Flows

Uncertainty Quantification of Expanding High-Enthalpy Air Flows

Transport Cross Sections and Collision Integrals for O($$^{3}$$P)–O($$^{3}$$P) Interaction

Numerical Research for Hypersonic 3D Flow with High-Temperature Effect and Catalytic Conditions

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