(407e) Multi-Layer Multi-Component Adsorption Isotherm Model:Theoretical and Experimental Validation

Multi-layer
multi-component adsorption isotherm model: Theoretical and experimental
validation

Ju Weon Lee¹ Andreas Seidel-Morgenstern^{1, 2}

¹
Max-Planck-Institute for Dynamics of Complex Technical Systems, Magdeburg,
Germany

²
Institute of Process Engineering, Otto von Guericke University, Magdeburg,
Germany

In liquid chromatography, one of many isotherm models
introduced based on theoretical and heuristic backgrounds is selected to
analyze and describe the retention behaviors of adsorbates [1, 2]. However,
most conventional isotherm models are not suitable in cases that adsorbate
mixture shows ununiformed behaviors, e.g. in a certain range isotherm shape is
changed from Langmuir-like to anti-Langmuir and vice versa, or some components
shows different behaviors. Recently, several researchers introduced multi-layer
isotherm models for a single component to express theoretical clues for the
mixed isotherm behaviors [3-5].

In this work, a novel multi-layer multi-component (MLMC)
adsorption isotherm model developed on a theoretical basis was introduced to
explain the retention behaviors that the conventional theoretical isotherm
models cannot explain. The following equation shows the structure of the MLMC
model.

where M and N are the number of components and
adsorption layers, respectively.

Case Study: Mixed binary system (  )

For mixed binary systems (one component obeys a Langmuir-like
isotherm, and the other obeys an anti-Langmuir isotherm), a generalized
Langmuir isotherm model (concentration terms in the denominator can be assigned
to positive or negative) was introduced in a heuristic manner [6]. Figure 1
shows the simulated elution profiles with the MLMC model.

Figure 1. Simulated
concentration profiles of the binary mixtures with the MLMC model.

a) , b)

References

[1]   T.L.
Hill, “An Introduction to Statistical Thermodynamics” (1960) Dover Publications
Inc.

[2]   G.
Guiochon, S.G. Shirazi, A.M. Katti, “Fundamentals of Preparative and Nonlinear
Chromatography” (1994) Academic Press.

[3]   C.-H. Wang, B.J. Hwang, Chem. Eng. Sci. 55 (2000) 4311.

[4]   F.
Gritti, W. Piatkowski, G. Guiochon, J. Chromatogr. A 978 (2002) 81.

[5]   P.
Vajda, A. Felinger, J. Chromatogr. A 1324 (2014) 121.

[6]   M.
Mazzotti, J. Chromatogr. A 1126 (2006) 311.