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Monodisperse hard-sphere collisions

Finally, the change of kinetic energy due to collisions requires that [Pg.215]

The rest of this chapter is organized as follows. First, in Section 6.1, we consider the collision term for monodisperse hard-sphere collisions both for elastic and for inelastic particles. We introduce the kinetic closures due to Boltzmann (1872) and Enksog (1921) for the pair correlation function, and then derive the exact source terms for the velocity moments of arbitrary order and then for integer moments. Second, in Section 6.2, we consider the exact source terms for polydisperse hard-sphere collisions, deriving exact expressions for arbitrary and integer-order moments. Next, in Section 6.3, we consider simplified kinetic models for monodisperse and polydisperse systems that are derived from the exact collision source terms, and discuss their properties vis-d-vis the hard-sphere collision models. In Section 6.4, we discuss properties of the moment-transport equations derived from Eq. (6.1) with the hard-sphere collision models. Finally, in Section 6.5 we briefly describe how quadrature-based moment methods are applied to close the collision source terms for the velocity moments. [Pg.215]

In this section we will briefly review the collision model for binary hard-sphere collisions using the notation in Fox Vedula (2010). The change in the number-density function due to elastic hard-sphere collisions (Boltzmann, 1872 Cercignani, 1988 Chapman Cowling, 1961 Enksog, 1921) obeys an (unclosed) integral expression of the form  [Pg.215]

Because the collisions are elastic, the pre-collision velocities before inverse collisions are the same as the values after a direct collision (which is not the case for inelastic collisions, as will be discussed below). As a result, conservation of momentum and energy follows directly from the definitions of the pre-collision velocities since [Pg.216]

For inelastic collisions, the hard-sphere collision model is given by (Fox Vedula, 2010 Jenkins Mancini, 1989 Jenkins Richman, 1985) [Pg.216]

Monodisperse hard-sphere collisions In addition, conservation of momentum implies that... [Pg.215]

Monodisperse hard-sphere collisions functions about spatial point x yields... [Pg.221]

The moment-transport equations discussed above become more and more complicated as the order increases. Moreover, these equations are not closed. In quadrature-based moment methods, the velocity-distribution function is reconstructed from a finite set of moments, thereby providing a closure. In this section, we illustrate how the closure hypothesis is applied to solve the moment-transport equations with hard-sphere collisions. For clarity, we will consider the monodisperse case governed by Eq. (6.131). Formally, we can re-express this equation in conservative form ... [Pg.261]

See other pages where Monodisperse hard-sphere collisions is mentioned: [Pg.215]    [Pg.217]    [Pg.219]    [Pg.223]    [Pg.225]    [Pg.227]    [Pg.229]    [Pg.231]    [Pg.233]    [Pg.235]    [Pg.215]    [Pg.217]    [Pg.219]    [Pg.223]    [Pg.225]    [Pg.227]    [Pg.229]    [Pg.231]    [Pg.233]    [Pg.235]    [Pg.214]   


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