Abstract

Thermochemical nonequilibrium is one of the most challenging issues when dealing with hypersonic flows experienced by objects (space vehicles, meteoroids, space debris) at atmospheric entry. The case of a hypersonic flow past a sphere is considered as a test model for systems in strong chemical and thermal nonequilibrium conditions, mimicking the extreme environment experienced by objects entering a planetary atmosphere. The problem has been studied using the state-to-state approach, calculating directly the distribution of vibrational levels of O2 and N2, together with the flow field, including also viscous effects. Nonequilibrium distributions are observed and the results have been compared with macroscopic experimental data, showing that the state-to-state model is able to provide better capabilities for predicting experimental results than the traditional multitemperature approach. The use of graphics processing units allowed us to obtain these results in a two-dimensional configuration, opening additional perspectives in the investigation of reacting flows.4 MoreReceived 20 June 2018DOI:https://doi.org/10.1103/PhysRevFluids.4.033404©2019 American Physical SocietyPhysics Subject Headings (PhySH)Research AreasCompressible flowsHigh-speed flowReacting flowsShock wavesPhysical SystemsNonequilibrium systemsTechniquesNavier-Stokes equationFluid Dynamics