Talk:Ion chromatography (IC): Difference between revisions

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== Abstract ==
== Abstract ==
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== Abridged version  ==
== A brief explanation ==


In general chromatography denotes a method for the separation of substances. These substances are distributed between a stationary and a mobile phase. A column packing of Al<sub>2</sub>O<sub>3</sub>, activated carbon, ion exchanger, etc. or a piece of filter paper may be used as stationary phase. The mixture to be separated, i.e. the mobile phase, is either liquid (e.g. paper chromatography, ion exchange chromatography) or gaseous (gas chromatography). The surprisingly high separation efficiency of this relatively simple method is based on a times 100– 10000 repetition of single separation operations during the passage on the stationary phase. In order to achieve the separation of chemically similar substances by chromatography, the partition coefficients of the two materials on the stationary phase have to differ at least slightly.  
Cromatography is one of several methods that can be used for the separation of substances. The method is base on having two phases: a stationary and a mobile one. A piece of filter paper can serve as a stationary phase or a tube or column, as it is usually called, is packed with materials such as alumina, Al<sub>2</sub>O<sub>3</sub>, activated carbon, ion exchange resins, etc. The mixture to be separated is dissolved in an appropriate solvent, in the case of salts, distilled water is used, that also serves as the mobile phase and fed into the column. Because of the difference in affinity between the substances to be separated in both the mobile and the stationary phase, they are separated as more and more solvent is passed through the column. The reason for the name chromatography dates from the first separation of the different pigments found in spinach, such as chlorolphyl, carotenes, etc. so the stationary phase would be colored differently according to the affinity of the pigment for it.
 
For the case of ion chromatography, the ions are also distributed between the stationary and the mobile phase and their separation is dependent on the partition coefficient of each specific ion. The surprisingly high separation efficiency of this relatively simple method is based on a times 100–10000 repetition of individual separation operations during the on going passage of the moble phase through the stationary one. In order to achieve the separation of chemically similar substances by chromatography, the partition coefficients of the two materials on the stationary phase have to differ at least slightly.  


In the broadest sense, ion chromatography includes ion-exchange chromatography, ion exclusion chromatography, ion interaction chromatography (previously ion pair chromatography) and ion suppression chromatography.
In the broadest sense, ion chromatography includes ion-exchange chromatography, ion exclusion chromatography, ion interaction chromatography (previously ion pair chromatography) and ion suppression chromatography.
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The retention times <ref>the time required by the analyte for passing through the column, from injection to detection</ref> of the alkali and alkaline earth metals rise consequentially from lithium to cesium and magnesium to barium, because the polarizability of ions rises in the same direction, while the solvation ability rises in opposite directions. The same applies to halogen ions from flourine to iodine. For other ions, the situation is not so clear. However, the bi- or higher valent ions elute after the monovalent ions. Protons and hydroxyl ions have a large hydrate shell and therefore only a low elution strength. Retention behavior and selectivity of the separation are mainly influenced by pH- value, buffer <ref>acid-base pair that does not change in pH, when an acid or base is added</ref>, eluent ion<ref>carrier liquid or mobile phase of a gas</ref>, organic solvent '''additive or addition? (Lösungsmittelzusatz)''', and particularly heavy metals due to complexing agents.   
The retention times <ref>the time required by each of the individual ions, referred to as analyte. for passing through the column, from injection to detection</ref>. The retention times for alkali and alkaline earth metals rise sequentially from lithium to cesium and magnesium to barium, because the polarizability of ions increases similarly, while solvation, the ability of these cations to form a hydration shell around them, increases in the opposite direction. The same applies to halogen anions from flourine to iodine. For other ions, the situation is not so clear. However, the bi- or higher valent ions elute after the monovalent ions. Protons and hydroxyl ions have a large hydration shell and therefore only a low elution strength. Retention behavior and selectivity of the separation are mainly influenced by pH-value, buffer <ref>acid-base pair that does not change in pH, when an acid or base is added</ref>, eluent ion<ref>carrier liquid or mobile phase of a gas</ref>, organic solvent '''additive or addition? (Lösungsmittelzusatz)''', and particularly heavy metals due to complexing agents.   


The detector of choice for ion chromatography is the conductivity detector. Yet, in some cases other detectors provide good services.
The detector of choice for ion chromatography is the conductivity detector. Yet, in some cases other detectors provide good services.
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'''Advantage:'''
'''Advantage:'''
The ion chromatography can be used for the analysis of cations and anions. However, it is mostly used for detecting anions, because there are better methods for the detection of cations. Ion chromatography provides accurate quantitative analyses.
Ion chromatography can be used for the analysis of cations and anions. However, it is mostly used for detecting anions, because there are better methods for the detection of cations. Ion chromatography provides accurate quantitative analyses.




'''Disadvantage:'''
'''Disadvantage:'''
Only ions can be determined, complete salt-phases are determined by deduction, which is only possible for simple systems.
Only ion concentrations can be determined, and complete salt-phases are determined by deduction, which is only possible for simple systems.


==Weblinks==
==Weblinks==

Revision as of 16:50, 27 November 2012

Author: Hans-Jürgen Schwarz

back to Analysis of Salts

A brief explanation[edit]

Cromatography is one of several methods that can be used for the separation of substances. The method is base on having two phases: a stationary and a mobile one. A piece of filter paper can serve as a stationary phase or a tube or column, as it is usually called, is packed with materials such as alumina, Al2O3, activated carbon, ion exchange resins, etc. The mixture to be separated is dissolved in an appropriate solvent, in the case of salts, distilled water is used, that also serves as the mobile phase and fed into the column. Because of the difference in affinity between the substances to be separated in both the mobile and the stationary phase, they are separated as more and more solvent is passed through the column. The reason for the name chromatography dates from the first separation of the different pigments found in spinach, such as chlorolphyl, carotenes, etc. so the stationary phase would be colored differently according to the affinity of the pigment for it.

For the case of ion chromatography, the ions are also distributed between the stationary and the mobile phase and their separation is dependent on the partition coefficient of each specific ion. The surprisingly high separation efficiency of this relatively simple method is based on a times 100–10000 repetition of individual separation operations during the on going passage of the moble phase through the stationary one. In order to achieve the separation of chemically similar substances by chromatography, the partition coefficients of the two materials on the stationary phase have to differ at least slightly.

In the broadest sense, ion chromatography includes ion-exchange chromatography, ion exclusion chromatography, ion interaction chromatography (previously ion pair chromatography) and ion suppression chromatography.

Usually, the ion exchange chromatography is used for the detection of salt-forming ions[1]. In general, an exchanger’s affinity for an oppositely charged sample ion is greater, the higher the charge and the smaller the sample ion’s surrounding solvation molecules are. Furthermore, the affinity increases with the polarizability of the ions.


The retention times [2]. The retention times for alkali and alkaline earth metals rise sequentially from lithium to cesium and magnesium to barium, because the polarizability of ions increases similarly, while solvation, the ability of these cations to form a hydration shell around them, increases in the opposite direction. The same applies to halogen anions from flourine to iodine. For other ions, the situation is not so clear. However, the bi- or higher valent ions elute after the monovalent ions. Protons and hydroxyl ions have a large hydration shell and therefore only a low elution strength. Retention behavior and selectivity of the separation are mainly influenced by pH-value, buffer [3], eluent ion[4], organic solvent additive or addition? (Lösungsmittelzusatz), and particularly heavy metals due to complexing agents.

The detector of choice for ion chromatography is the conductivity detector. Yet, in some cases other detectors provide good services.


Advantage: Ion chromatography can be used for the analysis of cations and anions. However, it is mostly used for detecting anions, because there are better methods for the detection of cations. Ion chromatography provides accurate quantitative analyses.


Disadvantage: Only ion concentrations can be determined, and complete salt-phases are determined by deduction, which is only possible for simple systems.

Weblinks[edit]

  1. http://www.chemgapedia.de/vsengine/vlu/vsc/de/ch/8/bc/vlu/proteinanalytik/chromatographie.vlu/Page/vsc/de/ch/8/bc/proteinanalytik/methoden_protein/fplc.vscml.html
  2. the time required by each of the individual ions, referred to as analyte. for passing through the column, from injection to detection
  3. acid-base pair that does not change in pH, when an acid or base is added
  4. carrier liquid or mobile phase of a gas



SLeithaeuser 10:32, 21 September 2012 (CEST)