Abstract
An important aspect of constructing discrete velocity models (DVMs) for the Boltzmann equation is to obtain the right number of collision invariants. Unlike for the Boltzmann equation, for DVMs there can appear extra collision invariants, so called spurious collision invariants, in plus to the physical ones. A DVM with only physical collision invariants, and hence, without spurious ones, is called normal. The construction of such normal DVMs has been studied a lot in the literature for single species, but also for binary mixtures and recently extensively for multicomponent mixtures. In this paper, we address ways of constructing normal DVMs for polyatomic molecules (here represented by that each molecule has an internal energy, to account for non-translational energies, which can change during collisions), under the assumption that the set of allowed internal energies are finite. We present general algorithms for constructing such models, but we also give concrete examples of such constructions. This approach can also be combined with similar constructions of multicomponent mixtures to obtain multicomponent mixtures with polyatomic molecules, which is also briefly outlined. Then also, chemical reactions can be added.
Highlights
We consider the Boltzmann equation for polyatomic molecules [19,25,29], here represented by that each molecule has an internal energy that can change during collisions
The Boltzmann equation can be approximated by discrete velocity models (DVMs) up to any order [17,20,26,32], and these discrete approximations can be used for numerical methods, e.g., see [20,31] and references therein
In correspondence with the cases of binary mixtures [16] and multicomponent mixtures [10] we introduce the concepts of semisupernormal and supernormal DVMs for polyatomic molecules
Summary
We consider the Boltzmann equation for polyatomic molecules [19,25,29], here represented by that each molecule has an internal energy that can change during collisions. We consider here the problem of constructing DVMs for single species of polyatomic molecules with the right number of collision invariants and outline the extension to DVMs for mixtures of polyatomic molecules (cf [7]). We like to stress that it is always possible to extend our constructed DVMs to DVMs symmetric with respect to the axes by the method of one-extensions Another important issue is the one of approximating the full Boltzmann equation by DVMs, which have been addressed for single species of polyatomic molecules in e.g., [21] and for mixtures with polyatomic molecules in e.g., [28].
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