Zirconia stationary phases for extreme separations

C. J. Dunlap; C. V. McNeff; D. Stoll; P. W. Carr

Zirconia stationary phases for extreme separations

C. J. Dunlap, C. V. McNeff, D. Stoll, P. W. Carr

Chemistry (Twin Cities)

Research output: Contribution to journal › Review article › peer-review

30 Scopus citations

Abstract

Modified silica has proven to be a versatile stationary phase for reversed-phase LC separations, as long as the pH remains below -8 and the temperatures aren't too high. But why limit separations to certain ranges? Christopher Dunlap at Saint Mary's College, Clayton McNeff and Dwight Stoll at ZirChrom Separations, and Peter Carr at the University of Minnesota demonstrate how zirconia-based columns successfully and reproducibly handle separations at high temperatures and extreme pHs.

Original language	English (US)
Pages (from-to)	599A-607A
Journal	Analytical chemistry
Volume	73
Issue number	21
State	Published - Nov 1 2001

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AU - Dunlap, C. J.

AU - McNeff, C. V.

AU - Stoll, D.

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N2 - Modified silica has proven to be a versatile stationary phase for reversed-phase LC separations, as long as the pH remains below -8 and the temperatures aren't too high. But why limit separations to certain ranges? Christopher Dunlap at Saint Mary's College, Clayton McNeff and Dwight Stoll at ZirChrom Separations, and Peter Carr at the University of Minnesota demonstrate how zirconia-based columns successfully and reproducibly handle separations at high temperatures and extreme pHs.

AB - Modified silica has proven to be a versatile stationary phase for reversed-phase LC separations, as long as the pH remains below -8 and the temperatures aren't too high. But why limit separations to certain ranges? Christopher Dunlap at Saint Mary's College, Clayton McNeff and Dwight Stoll at ZirChrom Separations, and Peter Carr at the University of Minnesota demonstrate how zirconia-based columns successfully and reproducibly handle separations at high temperatures and extreme pHs.

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Zirconia stationary phases for extreme separations

Abstract

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