论文信息 - Improving the accuracy of the moments method for solving the aerosol general dynamic equation

Improving the accuracy of the moments method for solving the aerosol general dynamic equation

Abstract The General Dynamic Equation for aerosol evolution is converted into a set of ordinary differential equations for the moments Mm by multiplying by vm and integrating over particle volume, v. Closure of these equations is achieved by assuming a functional form for the moments, instead of the usual assumption of a functional form for the size distribution itself. Specifically, it is assumed that In(Mm) can be expressed as a pth-order polynomial in m. The time-dependent coefficients in the polynomial are found by solving (p + 1) differential equations numerically. The case p = 2 corresponds to the assumption that the size distribution is always log-normal but comparison with accurate solutions shows that increasing p increases the accuracy of the method for all processes considered (removal, condensation and Brownian coagulation). Particle loss during evaporation and achievement of a self-preserving form for Brownian coagulation are also considered. Inversion of the moment expression to obtain the size distribution using the Mellin inversion formula is discussed.

J. C. Barrett | J. Barrett | J. S. Jheeta | J. Jheeta

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