Acidity of Phenols (Cambridge (CIE) A Level Chemistry): Revision Note
Acidity of Phenols
Although phenol compounds contain an alcohol (-OH) group, they are weakly acidic
This is due to the delocalisation of one of the lone pairs from the oxygen atom into the aromatic ring
This increases the electron density of the ring and increases the acidic behaviour
Delocalisation of charge density
The conjugate base of phenol is the phenoxide ion
In the phenoxide ion, the negative charge on the oxygen is spread out over the entire ion
This is possible as one of the lone pairs on the oxygen atom overlaps with the delocalised π system of the ring
Because of this delocalisation, there is less charge density on the oxygen atom
The H+ ions are therefore not strongly attracted to the phenoxide ion and are less likely to reform the phenol molecule
This means that phenol is more likely to lose a proton (and act as an acid) rather than to gain a proton (and act as a base )
The equilibrium between phenol and the phenoxide ion
The negative charge is spread over the ion, causing the electrons to become less available for bonding with an incoming proton
Stability of the conjugate base
Phenol ionises to form a more stable negative phenoxide ion with its negative charge spread out
This means that phenol is more likely to undergo ionisation
The equilibrium position, therefore, lies further to the right and a higher proportion of phenol molecules donate a proton compared to for example water and ethanol
The phenol compound is, therefore, more likely to act as an acid rather than a base
Therefore, the position of equilibrium lies:
Further to the right-hand side favouring the dissociated phenoxide ions
Further to the left-hand side favouring the undissociated ethoxide and hydroxide ions
The equilibrium position of phenol and the phenoxide ion
Since the phenoxide ion formed from the ionisation of phenol is more stable than phenol itself, the equilibrium position lies further to the right-hand-side and phenol is more likely to act as an acid rather than a base
Relative Acidities of Water, Phenol & Ethanol
The pKa is a measure of the acidity of a substance
The values of water, phenol, and ethanol show that phenol is a stronger acid than ethanol and water
Relative acidity of ethanol, water & phenol table
Acid | Dissociation | pKa at 25 oC |
|---|---|---|
Ethanol | C2H5OH (aq) | 16 |
Water | H2O (l) | 14 |
Phenol | C6H5OH (aq) | 10 |
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OH– (aq) + H+ (aq)The order of acidity can be explained by looking at their conjugate bases which are formed from the dissociation of the compounds
Delocalisation of charge density
In the phenoxide ion (which is the conjugate base of phenol) the charge density on the oxygen atom is spread out over the entire ion
As a result, the electrons on the oxygen atom are less available for bond formation with a proton (H+ ion)
The conjugate base of ethanol is the ethoxide ion
The ethyl group in the ion is an electron-donating group that donates electron density to the oxygen atom
As a result, the electron density on the oxygen atom is more readily available for bond formation with a H+ ion
The equilibrium between ethanol and the ethanoate ion
The electron-donating alkyl group in the ethoxide ion concentrates charge density on the oxygen atom which can more easily bond an H+ ion
The conjugate base of water is the hydroxide ion
Since the charge density of the oxygen atom cannot become delocalised over a ring, the hydroxide ion more readily accepts an H+ ion compared to the phenoxide ion
Water is, therefore, a stronger base compared to phenol
However, as there are no electron-donating alkyl groups, less negative charge is concentrated on the oxygen atom which therefore less readily accepts an H+ ion compared to the ethoxide ion
Water is, therefore, a weaker base compared to ethanol
The equilibrium between water and the hydroxide ion
The hydroxide ion lacks an aromatic ring and electron-donating alkyl groups so water is a stronger base than phenol but a weaker base than ethanol
Therefore, the position of equilibrium lies:
Further to the right-hand side favouring the dissociated phenoxide ions
Further to the left-hand side favouring the undissociated ethoxide and hydroxide ions
Relative equilibrium positions for the dissociation of ethanol, water and phenol
The relative equilibria for the dissociation of ethanol, water and phenol mean that ethanol is the weakest acid, while phenol is the strongest acid
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