Schuster, Georg; Lindner, Wolfgang published the artcile< Comparative characterization of hydrophilic interaction liquid chromatography columns by linear solvation energy relationships>, Related Products of 21876-43-7, the main research area is hydrophilic interaction liquid chromatog column linear solvation energy relationship; acid organic hydrophilic interaction LC linear solvation energy relation; base organic hydrophilic interaction LC linear solvation energy relation.
Twenty-two com. available and home-made stationary phases with different surface modifications were compared under hydrophilic interaction liquid chromatog. (HILIC) conditions. The column set comprised neutral, basic, acidic, zwitterionic and mixed surface modifications. Retention data of 68 differently structured test solutes were acquired to generate retention models based on a linear solvation energy relation (LSER) approach. A recently modified solvation parameter model with two addnl. mol. descriptors was evaluated in terms of its universal applicability when electrostatic forces are enabled in addition to predominant partition phenomena. The suggested method could not be confirmed to be a standardized way to characterize HILIC systems when different operating conditions are applied. However, the significant contribution of the recently introduced charge descriptors (D- and D+) on explaining the interactions within HILIC systems was confirmed. The solvation parameter model is a useful tool in column development, to affirm or dismiss the preceding educated guess on how certain immobilized ligands will behave. Acidic modified surfaces (stationary phases) exhibit a very small hydrogen bond acceptor property and are less versatile when it comes to an even distribution of solutes along the retention window. Also, basic and neutral columns are more preferable for HILIC applications and might explain why only a limited variety of strong acidic modified HILIC columns, although found in literature, are available com.
Journal of Chromatography A published new progress about Electrostatic force. 21876-43-7 belongs to class pyridine-derivatives, and the molecular formula is C9H13NO3S, Related Products of 21876-43-7.