High-temperature reversed-phase high-performance liquid chromatographic analysis of a synthetic copolymer on a non-porous support

Influence of pore size on the separation of random and block copolymers by interactive liquid chromatography

Stationary phase materials with small pore diameters are often used for the separation of copolymers according to their chemical composition. The rationale for such a column selection is to minimize the influence of the molecular weight on the separation. In this paper, we describe a detailed study of the influence of the pore size on the retention and separation of poly(methylmethacrylate) (PMMA)-poly(butylmethacrylate) copolymers. We used normal-phase (NP) and reversed-phase (RP) columns with various pore diameters, as well as non-porous columns and a monolithic column. The pore size was found to affect the separation, especially for (co-)polymer molecules with characteristic diameters that roughly correspond to the exclusion limit of the column. Also possibilities to separate block copolymers according to block length are strictly investigated. The making of one block in a di-block (DB) copolymer "invisible" can only be fulfilled if the "invisible" block does not play any role in the separation.

High-temperature liquid chromatography

The present state of the active use of elevated temperatures in liquid chromatography is reviewed, including the effects on retention, selectivity and efficiency. Separations in aqueous mobile phases as well as non-aqueous media are discussed, with particular emphasis on narrow-bore columns.

Separation of polyesters by gradient reversed-phase high-performance liquid chromatography on a 1.5 microm non-porous column

Efficient separation of polyesters composed of a large number of individual oligomers was achieved on a 1.5 microm "non-porous" octadecylsilyl (ODS) silica support by gradient high-performance reversed-phase liquid chromatography (gRP-HPLC) with a mobile phase of acetonitrile, aqueous trifluoroacetic acid (0.2%) and tetrahydrofuran at ambient temperature and signal monitoring by UV absorption at 280 nm. Substantial signal splitting of oligomers in the low molecular weight (Mr) region is indicative that separation not only occurs with respect to molecular weight distribution (MWD) but also to chemical composition distribution (CCD) and functionality type distribution (FTD). Although separation according to CCD and FTD decreases with increasing number of oligomers, co-elution of species with identical number of repeat units but differing in either structure of repeat units or end-groups can be assumed from the relatively broad signals succeeding the aforementioned peaks showing at least partial resolution. Despite the observation that high Mr oligomers elute as sharp signals, the preceding observations suggest that each of these peaks presumably composes of more than one individual component. The polyester oligomers are eluted in the range of increasing Mr and therefore, either separation according to MWD or CCD/FTD was at least achieved for the low Mr sample constituents. Some principal mechanistic aspects of separation are discussed and adsorption seems to play the dominant role. The detection limit, defined as that sample amount yielding an unequivocal recognition on the base of its characteristic chromatographic fingerprint pattern was about 5,000 ppm for the pair Alftalat 3258 - Alftalat 3352 and 10,000 ppm for the pair Crylcoat 430 - Crylcoat 801.

Molded continuous poly(styrene-co-divinylbenzene) rod as a separation medium for the very fast separation of polymers. Comparison of the chromatographic properties of the monolithic rod with columns packed with porous and non-porous beads in high-performance liquid chromatography of polystyrenes

Gradient elution separations of polystyrene standards in a monolithic molded 50 x 8 mm I.D. poly(styrene-co-divinylbenzene) rod column and in 50 x 8 mm I.D. and 30 x 4.1 mm I.D. columns packed with porous and non-porous poly(styrene-co-divinylbenzene) beads has been carried out. All of these separation media differ in shape and porosity. Excellent separations of eight polystyrene standards were achieved with both the molded monolithic rod and porous beads at moderate flow-rates. However, the monolithic medium proved to be superior for high-speed separations using very steep gradients at a flow-rate of 20 ml/min. Three polystyrene standards were separated in the rod column within 4 s. The separation in the column packed with non-porous beads was poor at flow-rates of 2-8 ml/min, while higher flow-rates led to an unacceptably high back pressure.

Molded monolithic rod of macroporous poly(styrene-co-divinylbenzene) as a separation medium for HPLC of synthetic polymers: on-column precipitation--redissolution chromatography as an alternative to size exclusion chromatography of styrene oligomers and polymers

A process for the separation of styrene oligomers and polymers by size and composition using a novel separation medium has been demonstrated. The process involves precipitation of the macromolecules on the molded macroporous rod columns, followed by progressive elution utilizing a simple gradient of the mobile phase. Molded macroporous rod columns are ideally suited for this technique because convection through the large pores of the rod enhances the mass transport of large analyte molecules and accelerates the separation process. Styrene oligomers and polymers are separated in a 50-mm x 8-mm-i.d. column using a solvent gradient composed of a poor solvent such as water, methanol, or acetonitrile and increasing amounts of a good solvent, tetrahydrofuran. Excellent separations are obtained, demonstrating that precipitation-redissolution can be a suitable alternate to size exclusion chromatography (SEC) of some polymers. Compared to SEC, the gradient elution separation can be achieved at higher flow rates in a much shorter time. Precipitation-redissolution with gradient elution can also be used for the separation of copolymers, for which the process is controlled not only by molecular weight but also by the composition of the copolymers.