Article ID | Journal | Published Year | Pages | File Type |
---|---|---|---|---|
159287 | Chemical Engineering Science | 2005 | 8 Pages |
The integral equation for isotherms is reviewed in order to select simple, practical, high-performance energy distributions from among the numerous existing models. Adsorption equilibria can be derived from occupation indices of suitable distributed energy levels. For mono sites, the occupation index is a Fermi–Dirac function. Whether a surface is energetically heterogeneous or homogeneous depends on the ratio of the breadth of the energy level distribution σσ to the thermal fluctuation kTkT. Although, there are only a few energy distributions for which analytic isotherm equations are known, the numerical evaluation shows general properties: the symmetry point Θ=12, the temperature domain for real or ideal behaviour and isotherm shapes without extrema. As an example, experimental equilibria of CO at molecular sieve 5A are fitted to a hyperbolic energy distribution using four physical parameters: the reference loading, a reference fluid phase pressure φ(Θ=12,Tref), the mean value and the standard deviation of the adsorption energy level distribution.