Date of Graduation

1998

Document Type

Dissertation/Thesis

Abstract

The stationary phase is at the heart of chromatographic separation techniques. In the pursuit of higher separation efficiency and resolving power, methods for the synthesis of novel polymeric stationary phases were developed. These stationary phases were evaluated using microscale separation techniques that have inherent high efficiency: open-tubular liquid chromatography (OT-LC), open-tubular capillary electrochromatography (OT-CEC), and packed column capillary electrochromatography (PC-CEC). A new technique was developed for the in situ synthesis of thin film polymer stationary phases inside small diameter fused silica capillaries. This technique allows the use of readily available and inexpensive polyimide jacketed capillaries, and provides greater control over the experimental conditions compared to other similar techniques. The versatility of the monomers—methacrylates—made it possible to employ the same basic experimental setups and conditions for the syntheses of various types of stationary phases that were used in reverse phase, ion exchange, and chiral separations. Detailed studies were conducted on the effects of various experimental parameters on the chromatographic performance of these stationary phases. High efficiency and resolution were achieved without extensive optimization of the separation conditions. One particular type of polymer studied herein is of great interest: molecular imprinted polymer (MIP). Methods were developed for the synthesis of MIPs in two formats: as bonded thin films inside fused silica capillaries, and as uniform-sized polymer particles. These MIPs were tested using chromatographic methods for chiral separation and screening of library compounds. The physical properties of these materials were also characterized by scanning electron microscopy and particle size distribution experiments.

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