Structural Isomers (DP IB Chemistry)
Revision Note
Structural Isomers
What are isomers?
Isomers are compounds that have the same molecular formula but a different arrangement of atoms
One group of isomers is the structural isomers
These are compounds that have the same molecular formula but different structural formulae
Isomers of C3H6
Propene and cyclopropane are both made of 3 carbon and 6 hydrogen atoms but the structure of the two molecules differs
There are three different types of structural isomerism:
Functional group isomerism
Positional isomerism
Branched chain isomerism
Functional group isomerism
When different functional groups result in the same molecular formula, functional group isomers arise
These isomers have very different chemical properties as they have different functional groups
Functional group isomers of C4H10O
Both compounds have the same molecular formula however butan-1-ol contains an alcohol functional group and ethoxyethane an ether functional group
It can help to be aware of which homologous series can be functional group isomers of each other:
Alkenes and cycloalkanes
Alcohols and ethers
Aldehydes and ketones
Positional isomerism
Positional isomers arise from differences in the position of a functional group in each isomer
This literally means that the functional group is located on different carbon atoms
Position isomers of butanol, C4H9OH, diagram
Both compounds are made up of 4 carbon, 10 hydrogen and one oxygen atom. However, the alcohol / OH group is located on different carbon atoms
In the example above, the functional group is the alcohol / OH group
The OH group can be attached to carbon-1, which gives rise to butan-1-ol
The OH group can be attached to carbon-2, which gives rise to butan-2-ol
Careful: In the butan-1-ol diagram, it appears that the OH group is attached to carbon-4
If you imagine looking at the molecule from the other side, you would see that the OH group is attached to carbon-1
The same is true of butan-2-ol, where the OH group appear to be attached to carbon-3
Some organic compounds that can be described as having primary, secondary or tertiary structures will exhibit isomerism
The terms primary, secondary and tertiary relate to the number of carbon atoms that the functional group carbon is attached to
Demonstrating primary, secondary and tertiary structures in alcohols
Classifying primary, secondary and tertiary alcohols and alcohols with more than one alcohol group
Alcohols, e.g. propanol
The primary alcohol propan-1-ol and the secondary alcohol propan-2-ol are position isomers of each other
Careful: The tertiary alcohol 2-methylpropan-2-ol is another isomer but it is branched chain not position isomerism
Halogenoalkanes, e.g. C4H11Br
The primary halogenoalkane 1-bromobutane and the secondary halogenoalkane 2-bromobutane are position isomers of each other
Careful: The tertiary halogenoalkane 2-bromo-2-methylpropane is another isomer but, again, it is branched chain not position isomerism
Branched chain isomerism
Branch-Chain isomerism is when compounds have the same molecular formula, but their longest hydrocarbon chain is not the same
This is caused by branching, i.e. where the longest hydrocarbon is broken into smaller pieces and some of these smaller pieces are added as side-chains / branches
Isomers of C5H12
Both compounds contain 5 carbon and 12 hydrogen atoms. However, the longest carbon chain in pentane is 5 and in 2,2-dimethylpropane it is 3 (with two methyl branches)
Isomerism in amines
Amines follow a slightly different classification system to alcohols and halogenoalkanes, although the terms primary, secondary and tertiary are still used
The classification is based on the number of alkyl groups attached to the nitrogen in the amine
Primary amines are those in which the nitrogen is attached to one other carbon atom (or alkyl group)
In secondary amines, the nitrogen atom is attached to two other carbon atoms (or alkyl groups)
In tertiary amines, the nitrogen is attached to three other carbon atoms (or alkyl groups)
Examples of primary, secondary and tertiary amines
The number of carbons attached to the nitrogen atom indicate if an amine is primary (1 carbon), secondary (2 carbons) or tertiary (3 carbons)
This means that amines do show isomerism
It is ambiguous whether isomerism in amines is position or branched chain
You should be able to deduce all possible isomers for organic compounds knowing their molecular formula
Worked Example
How many structural isomers are there of C3H6Br2?
Answer:
Step 1: Draw a displayed formula of the compound
Step 2: Determine whether there is functional group, branched chain or positional isomerism
Functional group?
No, Br is the only functional group present
Branched chain?
No, the longest carbon chain is 3 carbons which cannot branch:
Positional?
Yes, there are two bromine atoms that can be bonded to different carbon atoms
Worked Example
How many isomers are there of the compound with molecular formula C4H10?
Answer:
Step 1: Draw one possible structural formula of the compound
Step 2: Determine whether it is a functional group, branched chain or positional isomerism
Functional group?
No, there are no functional groups
Positional?
No, as there are no functional groups which can be positioned on different carbon atoms
Branched chain
Yes, a carbon chain containing 4 carbons is the smallest chain that can exhibit branched chain isomerism
Examiner Tips and Tricks
Don't be fooled by molecules by bending and turning through 90 degrees - that does not make them isomers. The best test is to try and name them - isomers will have a different name.
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