Separate HTML for Scripted Foil 8 Continuum Physics as an approximation to Particle Dynamics

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Foil 8 Continuum Physics as an approximation to Particle Dynamics

From CPS615-Physical Simulation Techniques and Structure of CFD Equations Delivered Lectures of CPS615 Basic Simulation Track for Computational Science -- 14 November 96. by Geoffrey C. Fox *

Secs 228.9

Replace particle description by average. 1023 molecules in a molar volume is too many to handle numerically. So divide full system into a large number of "small" volumes dV such that:

Macroscopic Properties: Temperature, velocity, pressure are essentially constant in volume

In principle, use statistical physics (or Particle Dynamics averaged as "Transport Equations") to describe volume dV in terms of macroscopic (ensemble) properties for volume

Volume size = dV must be small enough so macroscopic properties are indeed constant; dV must be large enough so can average over molecular motion to define properties

As typical molecule is 10-8 cm in linear dimension, these constraints are not hard
Breaks down sometimes e.g. leading edges at shuttle reentry etc. Then you augment continuum approach (computational fluid dynamics) with explicit particle method

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