A New Rotational Relaxation Model for Use in Hypersonic Computational Fluid Mechanics
Abstract
The theoretical basis for the Landau Teller equation commonly used to model rotational nonequilibrium is reviewed. Several assumptions underlying this model are indicated to be unrealistic for rarefied hypersonic flow. A new rotational nonequilibrium model based on recent measurements up to 2000K of quantum state transition rates is presented. The new model is applied to the continuum study of normal shock wave structure using both the Burnett equations and a simplified nonlinear constitutive relation. Comparisons are made between shock wave temperature profiles generated from the new model and those generated using the Landau Teller model. Comparisons of shock reciprocal thicknesses between experimental data for nitrogen and continuum solutions using both rotational models are made. The new rotational model agrees well with experiment up to Mach 6, and under predicts shock thickness at higher Mach numbers. The Landau Teller model agrees well with experimental shock thickness up to Mach 3, and over predicts the thickness at higher Mach numbers. A modification to the rotational collision number in the Landau Teller model is found to give results which agree with experimental shock thicknesses at all Mach numbers up to 11. Reprints.
Document Details
- Document Type
- Technical Report
- Publication Date
- Jun 14, 1989
- Accession Number
- ADA212300
Entities
People
- Chul Park
- Dean R. Chapman
- Forrest E. Lumpkin Iii
Organizations
- Stanford University