What Is Chromatography Used For?

Chromatography is a widely used analytical technique in IB Chemistry Topic 11 (Measurement & Data Processing) and Topic 21 (HL Organic Chemistry). It separates components of a mixture based on their interactions with a mobile phase and a stationary phase. This allows chemists to identify compounds, check purity, and analyze complex mixtures. Chromatography is fast, accurate, and essential across chemistry, biology, and environmental science.

What Is Chromatography Used For?

Chromatography is used to separate, identify, and sometimes quantify the components of a mixture.

It relies on the principle that different substances travel at different speeds depending on their attraction to a stationary phase and their solubility in a mobile phase.

In simpler terms:

• Components that are more soluble in the mobile phase move faster.
• Components that are more attracted to the stationary phase move slower.

This difference in movement creates separation.

Why Chromatography Works

Chromatography is based on:

• Differences in polarity
• Differences in solubility
• Differences in intermolecular forces
• Differences in volatility (for gas chromatography)

Each compound interacts differently with the two phases, leading to distinct movement patterns.

Major Uses of Chromatography

Chromatography is used in virtually every field of science.

1. Identifying components of a mixture

Chromatography can separate unknown mixtures, allowing chemists to determine what compounds are present.

2. Checking purity

A pure substance produces a single peak or spot.
Mixtures show multiple spots or peaks.

3. Monitoring reactions

Chemists can track:

• Whether a reaction has finished
• Which products formed
• Whether impurities remain

4. Separating very similar substances

Chromatography is sensitive enough to separate:

• Structural isomers
• Stereoisomers
• Compounds with similar boiling points

5. Quantifying components

Advanced methods like HPLC and GC can measure exact amounts.

Types of Chromatography Used in IB Chemistry

IB focuses on three main types:

1. Paper Chromatography

• Stationary phase: paper
• Mobile phase: solvent
• Used for inks, dyes, food colorings

Simple and visual, ideal for basic separation.

2. Thin-Layer Chromatography (TLC)

• Stationary phase: silica or alumina on a plate
• Mobile phase: solvent
• More accurate than paper chromatography

TLC is widely used for reaction monitoring.

3. Gas Chromatography (GC)

• Mobile phase: inert gas (He or N₂)
• Stationary phase: liquid coating inside a column
• Used for volatile compounds

GC produces precise separation and works with mass spectrometry (GC–MS) for full identification.

Interpreting Chromatography Results

Rf Value (for TLC and paper chromatography)

Rf = distance moved by substance ÷ distance moved by solvent

Rf values:

• Range from 0 to 1
• Are reproducible under identical conditions
• Help identify compounds by comparison to known standards

Peak Retention Time (in GC)

Retention time:

• Indicates how long a compound stays in the column
• Identifies compounds with high precision
• Depends on polarity, volatility, and temperature

Factors Affecting Chromatography

Several variables influence separation quality:

1. Polarity of solvent — more polar solvents move polar compounds further.
2. Strength of attraction to stationary phase — stronger attraction slows movement.
3. Temperature (in GC) — higher temperature → faster movement.
4. Molecular mass — heavier molecules often move slower.

Optimizing these factors improves separation resolution.

Real-World Applications

Chromatography is used in:

• Drug testing
• Food safety and contamination analysis
• Water and environmental monitoring
• Pharmaceutical purity checks
• Forensic science
• Biochemical research

Its versatility makes it one of the most important analytical techniques.

Common IB Misunderstandings

“Rf values are the same for every solvent.”

False—Rf values depend strongly on the solvent.

“Large spots on TLC mean high concentration.”

Spot size can be affected by how the sample was applied.

“GC can analyze solids.”

Only volatile compounds can be used in GC.

“Chromatography gives molecular structures.”

Chromatography separates mixtures; it does not directly reveal structure.

FAQs

Why do some spots move further in chromatography?

Because they are more soluble in the mobile phase or less attracted to the stationary phase.

Can chromatography separate isomers?

Yes—especially with GC and TLC, which can distinguish molecules with subtle differences.

Does chromatography destroy the sample?

TLC and paper chromatography do not; GC may due to heating.

Conclusion

Chromatography is a technique used to separate, identify, and analyze components of a mixture. By exploiting differences in polarity, solubility, and intermolecular interactions, chromatography can isolate compounds with precision. In IB Chemistry, understanding chromatography is essential for interpreting separations, analyzing mixtures, and solving real-world chemical problems.