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High Performance Liquid Chromatography

Modern liquid column chromatography (LC) has developed rapidly since 1969 to become a standard method of separation. If the statisticians are to be believed, the recent growth of LC has been the most specta­ cular development in analytical chemistry and has not yet abated be­ cause its vast potentia...

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Bibliographic Details
Main Author: Engelhardt, Heinz
Format: eBook
Language:English
Published: Berlin, Heidelberg Springer Berlin Heidelberg 1979, 1979
Edition:1st ed. 1979
Series:Chemical Laboratory Practice
Subjects:
Environmental Chemistry
Analytical Chemistry
Biochemistry
Online Access:
Collection: Springer Book Archives -2004 - Collection details see MPG.ReNa
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245 0 0 |a High Performance Liquid Chromatography  |h Elektronische Ressource  |c by Heinz Engelhardt 
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260 |a Berlin, Heidelberg  |b Springer Berlin Heidelberg  |c 1979, 1979 
300 |a XII, 254 p  |b online resource 
505 0 |a I. Chromatographic Processes -- References Chapter I -- II. Fundamentals of Chromatography -- A. Retention -- B. Linear Flow Rate, Porosity, Permeability -- C. Band Broadening -- D. Resolution -- E. Dependence of Band Broadening on Flow Rate -- F. Band Broadening and Particle Size -- G. Extra-Column Band Broadening -- H. Optimum Analysis Conditions and Analysis Time -- I. Selection of a Suitable Column -- References Chapter II -- III. Equipment for HPLC -- A. Solvent Reservoir — Degassing of the Eluent -- B. Pumps -- C. Damping of the Pulsations -- D. Sample Introduction -- E. The Column -- F. Thermostating -- G. Measurement of the Flow Rate -- H. Fraction Collectors -- I. Recorders -- J. Instrumentation for Gradient Elution -- K. Safety Measures -- References Chapter III -- IV. Detectors -- A. UV Detectors -- B. Differential Refractometer -- C. Microadsorption Detector -- D. Transport Detector (Flame Ionization Detector) -- E. Fluorescence Detector -- F. Other Detectors --  
505 0 |a A. Introduction -- B. Basics of Exclusion Chromatography -- C. Stationary Phases for Exclusion Chromatography -- D. Applications of Exclusion Chromatography -- References Chapter IX -- X. Selection of the Separation System -- References Chapter X -- XI. Special Techniques -- A. Preparative Chromatography -- B. Qualitative Analysis -- C. Quantitative Analysis -- D. Trace Analysis -- References Chapter XI -- XII. Purification of Solvents -- References Chapter XII. 
505 0 |a G. Comparison of the Important Detectors -- H. Reaction Detectors -- References Chapter IV -- V. Stationary Phases -- A. Packing Materials for Adsorption and Partition Chromatography -- B. Chemically Modified Supports -- C. Ion Exchangers -- D. Stationary Phases for Exclusion Chromatography -- References Chapter V -- VI. Adsorption Chromatography -- I. Polar Stationary Phases -- II. Nonpolar Stationary Phases -- III. The General Elution Problem -- IV. Applications of Adsorption Chromatography -- References Chapter VI -- VII. Partition Chromatography -- A. Introduction -- B. Supports and Liquid Phases -- C. Properties of the Column -- D. Applications -- E. Ion-pair Chromatography -- References Chapter VII -- VIII. Ion-Exchange Chromatography -- A. Principle -- B. Ion Exchange Materials -- C. Characterization of the Ion Exchangers -- D. Optimizing aSeparation -- E. Applications -- References Chapter VIII -- IX. Exclusion Chromatography. Gel Permeation Chromatography --  
653 |a Environmental chemistry 
653 |a Analytical chemistry 
653 |a Environmental Chemistry 
653 |a Analytical Chemistry 
653 |a Biochemistry 
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520 |a Modern liquid column chromatography (LC) has developed rapidly since 1969 to become a standard method of separation. If the statisticians are to be believed, the recent growth of LC has been the most specta­ cular development in analytical chemistry and has not yet abated be­ cause its vast potential for application remains to be fully exploit­ ed. Significant factors contributing to this continued rise are the simplicity and low cost of the required basic equipment and the rela­ tive ease of acquiring and interpreting the data. Unfortunately, in LC, as so often in the field of analytical chemistry, the available commercial instruments are frequently far more complicated - and consequently far more expensive - than is nec­ essary for routine application. Therein also lies the risk of propa­ gating a "black box" philosophy that would be particularly detrimen­ tal to chromatography. Moreover, it appears to have been forgotten, as was done previously with gas chromatography, that inadequate sep­ aration by a column can be remedied only with great difficulty, if at all, by electronic means. Also, whether the capillary columns recent­ ly advocated with great enthusiasm for LC will fulfill the expecta­ tions of their proponents is highly questionable unless someone comes up with some new and revolutionary ideas 

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