𝔖 Bobbio Scriptorium
✦   LIBER   ✦

Solution of Tung's axial dispersion equation by numerical techniques

✍ Scribed by T. Ishige; S.-I. Lee; A. E. Hamielec

Publisher
John Wiley and Sons
Year
1971
Tongue
English
Weight
601 KB
Volume
15
Category
Article
ISSN
0021-8995

No coin nor oath required. For personal study only.

πŸ“œ SIMILAR VOLUMES

Dispersion in gel permeation chromatogra
Dispersion in gel permeation chromatography. A rapid numerical solution to Tung's integral equation
✍ J. A. M. Smit; C. J. P. Hoogervorst; A. J. Staverman πŸ“‚ Article πŸ“… 1971 πŸ› John Wiley and Sons 🌐 English βš– 571 KB

## Abstract A rapid iteration method has been developed to correct the molecular weight averages calculated from raw GPC data for dispersion. Though simple in its performance, it covers the general case that the instrumental spreading characteristics (Tung's resolution factor __h__) depend on the e

Numerical solution of Helmholtz equation
Numerical solution of Helmholtz equation by the modified Hopfield finite difference techniques
✍ Mehdi Dehghan; Mojtaba Nourian; Mohammad B. Menhaj πŸ“‚ Article πŸ“… 2009 πŸ› John Wiley and Sons 🌐 English βš– 1021 KB

## Abstract One property of the Hopfield neural networks is the monotone minimization of energy as time proceeds. In this article, this property is applied to minimize the energy functions obtained by finite difference techniques of the Helmholtz‐equation. The mathematical representation and correl

Analysis of some dispersion corrected nu
Analysis of some dispersion corrected numerical schemes for solution of the transport equation
✍ Martinus T H. Van Genuchten; William G. Gray πŸ“‚ Article πŸ“… 1978 πŸ› John Wiley and Sons 🌐 English βš– 684 KB

## Abstract In the last decade or so finite element techniques have been applied with increased frequency to contaminant transport problems. Whereas most of the attention has focused on finite element approximations of spatial derivatives, standard finite difference techniques are generally used fo