After the sample enters the flow path, the mobile phase carries the sample to the column, where the separation occurs.

Columns can function in ambient air but are generally thermostatted and housed within a temperature-controlled column compartment. Proper column temperature control is essential to conserving retention time precision, selectivity, and separation efficiency.

A general rule to remember is that as the column temperature increases, analyte retention decreases, leading to faster separation.

How HPLC columns work
Representation of a sample mixture eluting and separating on the column at different rates.

HPLC columns contain a stationary phase bonded to a support material, usually porous silica particles, to provide a large surface area. The stationary phase provides the basis for separating sample components.

Stationary phase chemistry dictates the affinity of the sample components to stick or retain on the column as the mobile phase moves the sample through the column. As a result, the sample components traverse the column and elute at different rates.

For example, you can visualize a mixture (A) containing multiple components represented as a grey band introduced at the front, or head, of the column.

As the mobile phase moves the mixture through the column, the red component (B) retains more strongly than the purple. As a result, the purple and blue components move through the column faster and are the first ‘bands’ to elute from the column (C). The green, yellow, and red bands retain longer and elute later (D).

The physiochemical properties of a sample, stationary phase chemistry, mobile phase composition, flow rate, and column temperature determine the rate at which components travel through the column. Researchers can choose from various stationary phase chemistries and column dimensions like the length, inner diameter, and support particle sizes. 

Column type

Stationary phase

Mobile phase

Applications

Reversed Phase (RP)

Non-polar such as C18 or phenyl

Mixture of water and polar organic solvent

Accounts for a majority of HPLC separations

Normal Phase (NP)

Polar such as unbound silica

Mixture of less-polar organic solvents

Water-insoluble samples and isomers

Hydrophilic Interaction (HILIC)

Polar such as silica or amide-bonded phase

Mixture of water and non-polar organic solvent

Highly polar samples poorly retained by reverse phase liquid chromatography

Ion Exchange (IEX)

Ionizable groups

Usually an aqueous solution of a salt plus a buffer

Ionizable samples and large biomolecules

Ion Pair

Non-polar reversed phase columns

Non-polar conditions plus an ion pairing reagent

Acids or bases weakly retained by reversed phase

Chiral

Chiral groups such as polysaccharides or cyclodextrins

Analyte and SP dependent, can be RP, NP, polar organic, etc

Separation/purification of enantiomers, such as racemic drug mixtures

Hydrophobic Interaction (HIC)

Non-polar, short alkyl chains or phenyl

High salt buffer gradient, non-denaturing conditions

Proteins, often antibodies

Size Exclusion (SEC)

An inert column such as a dextran polymer

Used with either an aqueous or organic mobile phase

Large biomolecules or synthetic polymers

Learn more about the different HPLC column types and applications ›

Easily find the correct column with our digital LC column selection guide ›

 
 
 
FAQ

Most common HPLC columns are made from stainless steel and packed with porous silica particles that are typically modified, e.g., a C18 bonding is a common choice in reversed-phase HPLC. However, there is a high variety of HPLC column hardware and packing material.

Before beginning a new analysis, consider the physical and chemical properties of the analytes, the mode of analysis and how the analytes will interact with the surface of the chromatographic phase.

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