π In-Depth Theory
Structure of Carboxylic Acids
CARBOXYLIC ACIDS contain the functional group βCOOH (carboxyl group).
First four members:
Methanoic acid: HCOOH
Ethanoic acid: CHβCOOH (the acid in vinegar)
Propanoic acid: CβHβ
COOH
Butanoic acid: CβHβCOOH
NAMING:
Named from the corresponding alkane β replace '-e' with '-anoic acid'.
meth- β methanoic acid; eth- β ethanoic acid; prop- β propanoic acid.
PROPERTIES:
Acidic β donate HβΊ ions in solution.
Lower members dissolve in water β miscible.
Higher members less soluble.
Ethanoic acid (CHβCOOH) is the main component of vinegar.
Reactions of Carboxylic Acids
1. REACTION WITH CARBONATES:
Carboxylic acid + metal carbonate β salt + water + carbon dioxide
CHβCOOH + NaβCOβ β CHβCOONa + HβO + COβ
Ethanoic acid + sodium carbonate β sodium ethanoate + water + COβ
Same pattern as mineral acids reacting with carbonates.
COβ gas produced β effervescence (bubbling).
2. REACTION WITH METALS:
Carboxylic acid + metal β salt + hydrogen gas
More dilute/weaker reaction than mineral acids.
3. DISSOLVING IN WATER:
Forms weakly acidic solution β pH 3β5 (not as low as strong acids at the same concentration).
Due to weak dissociation.
4. REACTION WITH ALCOHOLS β ESTERIFICATION:
Carboxylic acid + alcohol β ester + water
CHβCOOH + CβHβ
OH β CHβCOOCβHβ
+ HβO
Ethanoic acid + ethanol β ethyl ethanoate + water
Conditions: acid catalyst (HβSOβ), warm, reversible reaction.
Esters have characteristic fruity smells β used in flavourings and perfumes.
Uses and Natural Sources
ETHANOIC ACID (CHβCOOH):
Main component of vinegar (typically 4β8% solution).
Preservative β inhibits bacterial growth.
Produced by oxidation of ethanol (e.g. wine left open).
METHANOIC ACID (HCOOH):
Found in ant stings (causes the burning sensation).
Used as a preservative in silage.
ESTERS:
Esters are formed from carboxylic acids + alcohols.
Fruity smells: ethyl ethanoate (nail polish remover), amyl acetate (banana), isoamyl acetate.
Used in flavourings, perfumes, solvents, plasticisers.
FATTY ACIDS:
Long-chain carboxylic acids (e.g. stearic acid, oleic acid).
Components of fats and oils β reacted with glycerol to form triglycerides.
CARBOXYLIC ACIDS AND pH:
Weaker than hydrochloric or sulfuric acid at the same concentration.
pH around 3β5 for typical dilute solutions.
Incompletely dissociate in water β equilibrium mixture of HA β HβΊ + Aβ».
β οΈ Common Mistake
Carboxylic acids are WEAK acids β they do not fully dissociate in water unlike HCl or HβSOβ. At the same concentration, carboxylic acid has a HIGHER pH than a strong acid. Esterification is REVERSIBLE β both ester + water and acid + alcohol are present at equilibrium.
π― Test Yourself
Question 1 of 2
1. What type of compound forms when ethanoic acid reacts with ethanol, and what are the conditions?
An ester (ethyl ethanoate) β acid catalyst (HβSOβ), warm conditions, reversible reaction
No reaction β carboxylic acids and alcohols don't react
An alkane β acid + alcohol always produces an alkane and water
An aldehyde β oxidation of the alcohol by the acid produces an aldehyde
2. Why does ethanoic acid have a higher pH than hydrochloric acid at the same concentration?
Ethanoic acid is a weak acid β it only partially dissociates in water, producing fewer HβΊ ions than HCl at the same concentration
Ethanoic acid has a larger molecule β bigger molecules are always less acidic
Hydrochloric acid contains chlorine β chlorine makes it more acidic than carbon compounds
Ethanoic acid reacts with water to form a base β neutralising some of its own acidity