Relative Acidities of Carboxylic Acids, Phenols & Alcohols (Cambridge (CIE) A Level Chemistry): Revision Note
Relative Acidities of Carboxylic Acids, Phenols & Alcohols
Carboxylic acids are compounds with a -COOH functional group
They can act as acids and lose a proton (H+ ion) in an aqueous solution to form carboxylate salts and water
Carboxylic acids forming carboxylate salts
Carboxylic acids dissociate in aqueous solutions to form carboxylate salts and water
However, carboxylic acids are only weak acids as the position of equilibrium lies well over to the left-hand side
The pKa values of carboxylic acids, phenols, and alcohols suggest that carboxylic acids are stronger acids than alcohols and phenols
The pKa is a measure of the relative strength of a species as an acid
The smaller the pKa value, the stronger the acid
Relative acidity of ethanol, phenol & carboxylic acids table
Acid | Dissociation | pKa at 25 oC |
|---|---|---|
Ethanol | C2H5OH (aq) | 16 |
Phenol | C6H5OH (aq) | 10 |
Ethanoic acid | CH3COOH (aq) | 4.8 |
Benzoic acid | C6H5COOH (aq) | 4.2 |
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C2H5O– (aq) + H+ (aq) format('truetype')%3Bfont-weight%3Anormal%3Bfont-style%3Anormal%3B%7D%3C%2Fstyle%3E%3C%2Fdefs%3E%3Ctext%20font-family%3D%22math1aa495e18c7e3a21a4e48923b92%22%20font-size%3D%2216%22%20text-anchor%3D%22middle%22%20x%3D%2210.5%22%20y%3D%2216%22%3E%26%23x21CC%3B%3C%2Ftext%3E%3C%2Fsvg%3E){kind=small}
C6H5O– (aq) + H+ (aq)
This order of relative acidities can be explained by looking at the strength of the O-H bond and the stability of the conjugate bases of the acids
Strength of O-H bond
In carboxylic acids, the electrons in the O-H bond are drawn towards the C-O bond
The electrons in the C-O bond are drawn towards the C=O bond
Overall, the O-H bond is weakened due to the carbonyl (C=O) group removing electron density from it and drawing it towards itself
Carboxylic acids can therefore more easily lose a proton compared to phenols and alcohols which lack this electron-withdrawing carbonyl group
Comparing OH bond strength of carboxylic acids, ethanol and phenol
The carbonyl group in carboxylic acids draws the electrons away from the O-H bond causing it to become weaker compared to the O-H bond in phenols and alcohols
Stability of carboxylate ions
The conjugate base of carboxylic acids is the carboxylate ion
The charge density on the oxygen atom is spread out over the carboxylate ion
This is because the charge is delocalised on an electronegative carbonyl oxygen atom
As a result, the electrons on the oxygen atom are less available for bond formation with an H+ ion to reform the undissociated acid molecule with -COOH group
The position of the dissociation equilibrium lies more to the right compared to alcohols and phenols
The equilibrium position of a carboxylic acid and its carboxylate ion
The carboxylate ion is stable due to the delocalisation of the charge density on the electronegative oxygen
Stability of alkoxide ions
The conjugate base of alcohols is the alkoxide ion
The alkyl 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 an H+ ion
Alkoxide ions also lack the ability to delocalise the charge density on the entire ion
The conjugate bases of alcohols are therefore less stable than the alcohols themselves and are more likely to reform the alcohol
This means that alcohols are weaker acids compared to carboxylic acids and phenols
The position of the dissociation equilibrium lies more to the left
The equilibrium position of an alcohol and its alkoxide ion
The electron-donating alkyl groups in alkoxide ions increase the electron density on the oxygen atom which is, therefore, more likely to bond with a H+ ion and reform the alcohol
Stability of phenoxide ions
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
This delocalisation of electrons stabilises the phenoxide 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 phenols is therefore more stable than phenol
However, since the delocalisation of charge density is on carbon atoms and not on electronegative oxygen atoms like in the carboxylate ion, phenoxide ions are less stable than carboxylate ions
Therefore, phenols are weaker acids relative to carboxylic acids
The position of the dissociation equilibrium lies more to the right compared to alcohols and more to the left compared to carboxylic acids
The equilibrium position of phenol and the phenoxide ion
The charge density is delocalised on the entire benzene ring in the phenoxide ions
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