The stochastic theory of size exclusion chromatography (SEC) was applied to analyze the peak shape of chromatograms obtained with a wide range of polystyrene standards on various columns. The columns were packed with stationary phases of different pore sizes. The stochasticdispersive model of SEC results in a peak shape model that fits well the symmetrical and asymmetrical peaks observed in SEC. From the peak shape parameters obtained after nonlinear parameter estimation, information can be gained regarding the fundamental characteristics of the size exclusion process. When a series of polymer standards are analyzed on one columnsin a manner similar to other methods of inverse chromatographysthe stationary phase can be characterized. The dependence of the ingress and the egress processes on the relative size of the macromolecule to the pore size was determined. We found that for small molecules the selectivity in SEC arises from the ingress process, while when the size of the macromolecule is comparable to that of the pores i.e., close to the exclusion limits the egress process will also strongly affect the selectivity.
Stochastic theory of size exclusion chromatography: Peak shape analysis on single columns
PASTI, Luisa;DONDI, Francesco;
2005
Abstract
The stochastic theory of size exclusion chromatography (SEC) was applied to analyze the peak shape of chromatograms obtained with a wide range of polystyrene standards on various columns. The columns were packed with stationary phases of different pore sizes. The stochasticdispersive model of SEC results in a peak shape model that fits well the symmetrical and asymmetrical peaks observed in SEC. From the peak shape parameters obtained after nonlinear parameter estimation, information can be gained regarding the fundamental characteristics of the size exclusion process. When a series of polymer standards are analyzed on one columnsin a manner similar to other methods of inverse chromatographysthe stationary phase can be characterized. The dependence of the ingress and the egress processes on the relative size of the macromolecule to the pore size was determined. We found that for small molecules the selectivity in SEC arises from the ingress process, while when the size of the macromolecule is comparable to that of the pores i.e., close to the exclusion limits the egress process will also strongly affect the selectivity.I documenti in SFERA sono protetti da copyright e tutti i diritti sono riservati, salvo diversa indicazione.