A homologous series is one of the foundational ideas in organic chemistry and appears early in IB Chemistry Topic 10. Understanding what defines these series makes it easier to predict chemical trends, balance equations, and identify functional groups. This article explains the concept clearly and shows how homologous series help organize organic compounds.
What Is a Homologous Series?
A homologous series is a family of organic compounds with the same functional group and general formula, where each successive member differs by a CH₂ unit.
For example, the alkane series:
- Methane: CH₄
- Ethane: C₂H₆
- Propane: C₃H₈
Each molecule increases by one CH₂ group.
This simple pattern provides structure and predictability in organic chemistry.
Key Characteristics of a Homologous Series
All members of a homologous series share these features:
1. Same Functional Group
The functional group defines the chemistry of the compound.
Examples:
- Alkanes: –
- Alkenes: C=C
- Alcohols: –OH
- Carboxylic acids: –COOH
2. Same General Formula
Members follow a consistent formula such as:
- Alkanes: CₙH₂ₙ₊₂
- Alkenes: CₙH₂ₙ
- Alcohols: CₙH₂ₙ₊₂O
3. Successive Members Differ by CH₂
Each step adds:
- One carbon
- Two hydrogens
This is why trends across a series are so regular.
4. Gradual Change in Physical Properties
As the chain length increases:
- Boiling point increases
- Viscosity increases
- Density increases
- Volatility decreases
These trends occur because longer chains have stronger London dispersion forces.
5. Similar Chemical Properties
Chemical reactivity is controlled by the functional group, so all members behave similarly in reactions.
For example, all alcohols can undergo oxidation or form esters.
Why Homologous Series Matter in IB Chemistry
Understanding homologous series helps you:
- Predict physical trends
- Identify functional groups
- Determine general formulas
- Classify organic molecules
- Recognize reaction patterns
- Balance equations more easily
- Understand systematic naming (IUPAC rules)
This comes up in topics such as organic structure, isomerism, and reaction mechanisms.
Examples of Common Homologous Series
Alkanes
- General formula: CₙH₂ₙ₊₂
- Functional group: none
- Properties: non-polar, unreactive, undergo substitution
Alkenes
- General formula: CₙH₂ₙ
- Functional group: C=C
- Properties: reactive, undergo addition reactions
Alcohols
- General formula: CₙH₂ₙ₊₂O
- Functional group: –OH
- Properties: hydrogen bonding, higher boiling points
Carboxylic Acids
- General formula: CₙH₂ₙO₂
- Functional group: –COOH
- Properties: acidic, form esters
Understanding these families makes organic chemistry far more systematic.
Chemical vs. Physical Trends
Homologous series show consistent physical changes but constant chemical behavior.
Physical trends:
- Boiling point increases with chain length
- Solubility decreases
- Viscosity increases
Chemical trends:
- Determined by the functional group
- Remain nearly identical across the series
This distinction is crucial for exam questions that ask you to compare compounds.
Why Each Member Is Called a “Homolog”
The term homolog simply means “one step higher in chain length.”
The CH₂ increase is what makes the pattern uniform and predictable.
FAQs
Why do boiling points increase in a homologous series?
Longer carbon chains have more electrons and greater surface area, leading to stronger London dispersion forces. More energy is required to separate molecules, so boiling points rise.
Are isomers part of the same homologous series?
Yes. As long as they contain the same functional group and general formula, structural isomers belong to the same series.
Is methane part of the alkene series?
No. Methane has no carbon–carbon double bond and does not follow the CₙH₂ₙ formula. It belongs only to the alkanes.
Conclusion
A homologous series is a family of organic compounds that share a functional group, follow a general formula, and differ by successive CH₂ units. This structure creates predictable physical trends and consistent chemical behavior. Mastering this concept provides a strong foundation for understanding organic reactions, patterns, and molecular structures in IB Chemistry.
