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  • 1
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    Theoretical study of the performance characteristics of a resistive electrode with a connection at the extreme edge (1976)
    Institute of Physics
    Details
    Publication Date: 1976-04-01
    Print ISSN: 0032-1028
    Topics: Physics
    Published by Institute of Physics
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    PAPER CURRENT
  • 2
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    Analysis of a semiclassical model for rotational transition probabilities (1975)
    In:  Other Sources
    Details
    Publication Date: 2011-08-16
    Description: A semiclassical model proposed by Pearson and Hansen (1974) for computing collision-induced transition probabilities in diatomic molecules is tested by the direct-simulation Monte Carlo method. Specifically, this model is described by point centers of repulsion for collision dynamics, and the resulting classical trajectories are used in conjunction with the Schroedinger equation for a rigid-rotator harmonic oscillator to compute the rotational energy transition probabilities necessary to evaluate the rotation-translation exchange phenomena. It is assumed that a single, average energy spacing exists between the initial state and possible final states for a given collision.
    Keywords: ATOMIC AND MOLECULAR PHYSICS
    Type: Physics of Fluids; 18; Sept
    Format: text
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    NASA TECHNICAL REPORTS
  • 3
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    Monte Carlo solution of Boltzmann equation for a simple model of highly nonequilibrium diatomic gases - Translational rotational energy relaxation (1978)
    In:  Other Sources
    Details
    Publication Date: 2011-08-17
    Description: Theoretical results pertaining to internally excited translational-rotational energy relaxation in a spatially uniform diatomic gas far removed from solid boundaries are obtained by solving the Boltzmann equation by means of the Monte Carlo direct simulation method. The analysis is based on calculations involving three different types of initial conditions: equilibrium, nonequilibrium-equipartition (i.e., equipartition is satisfied, but the distributions are perturbed), and nonequilibrium-nonequipartition (i.e., both equipartition and the distributions are perturbed). Results of monatomic-gas simulations are also included to facilitate comparisons with the coupled translational-rotational relaxation simulations, and some simulations for a normal shock-wave structure are briefly examined. The results show that: (1) single-step transitions are the significant mechanisms of intermodal energy transfer; (2) translational-rotational transitions are coupled most efficiently for low-lying states of rotationally excited molecules and least efficiently for highly rotationally excited molecules; and (3) relaxation occurs via a successive set of distributions that are not Maxwell-Boltzmann (nonlocal Maxwellian).
    Keywords: THERMODYNAMICS AND STATISTICAL PHYSICS
    Format: text
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    NASA TECHNICAL REPORTS
  • 4
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    Monte Carlo solution of Boltzmann equation for a simple model of highly nonequilibrium diatomic gases: Translational rotational energy relaxation (1978)
    In:  CASI
    Details
    Publication Date: 2019-06-27
    Description: The semiclassical transition probability was incorporated in the simulation for energy exchange between rotational and translational energy. The results provide details on the fundamental mechanisms of gas kinetics where analytical methods were impractical. The validity of the local Maxwellian assumption and relaxation time, rotational-translational energy transition, and a velocity analysis of the inelastic collision were discussed in detail.
    Keywords: THERMODYNAMICS AND STATISTICAL PHYSICS
    Type: NASA-TM-78481 , A-7405
    Format: application/pdf
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    NASA TECHNICAL REPORTS
  • 5
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    Monte Carlo calculations of diatomic molecule gas flows including rotational mode excitation (1976)
    In:  CASI
    Details
    Publication Date: 2019-06-27
    Description: The direct simulation Monte Carlo method was used to solve the Boltzmann equation for flows of an internally excited nonequilibrium gas, namely, of rotationally excited homonuclear diatomic nitrogen. The semi-classical transition probability model of Itikawa was investigated for its ability to simulate flow fields far from equilibrium. The behavior of diatomic nitrogen was examined for several different nonequilibrium initial states that are subjected to uniform mean flow without boundary interactions. A sample of 1000 model molecules was observed as the gas relaxed to a steady state starting from three specified initial states. The initial states considered are: (1) complete equilibrium, (2) nonequilibrium, equipartition (all rotational energy states are assigned the mean energy level obtained at equilibrium with a Boltzmann distribution at the translational temperature), and (3) nonequipartition (the mean rotational energy is different from the equilibrium mean value with respect to the translational energy states). In all cases investigated the present model satisfactorily simulated the principal features of the relaxation effects in nonequilibrium flow of diatomic molecules.
    Keywords: FLUID MECHANICS AND HEAT TRANSFER
    Type: NASA-TN-D-8100 , A-6196
    Format: application/pdf
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    NASA TECHNICAL REPORTS
  • 6
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    Solution of Boltzmann equation for highly nonequilibrium diatomic gases rotational translational energy relaxation (1979)
    In:  Other Sources
    Details
    Publication Date: 2019-07-13
    Description: The direct simulation Monte Carlo method is applied to solve the Boltzmann equation for collisions between internally excited diatomic gases in highly nonequilibrium states. The semiclassical transition probability is incorporated in the simulation for energy exchange between rotational and translational energy. The results provide details on the fundamental mechanisms of gas kinetics where analytical methods are impractical. The validity of the local Maxwellian assumption and relaxation time, rotational-translational energy transition, and a velocity analysis of the inelastic collision are discussed in detail.
    Keywords: ATOMIC AND MOLECULAR PHYSICS
    Type: Rarefied gas dynamics; Jul 03, 1978 - Jul 08, 1978; Cannes; France
    Format: text
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    NASA TECHNICAL REPORTS
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