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First exams 2025

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Strong & Weak Acids (SL IB Chemistry)

Revision Note

Philippa Platt

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Strong & Weak Acids

Strong acids

  • A strong acid is an acid that dissociates almost completely in aqueous solutions
    • Examples include HCl (hydrochloric acid), HNO3 (nitric acid) and H2SO4 (sulfuric acid)
    • The position of the equilibrium is so far over to the right that you can represent the reaction as an irreversible reaction

Diagram to show the dissociation of a strong acid

Diagram showing how strong acids dissociate

The diagram shows the complete dissociation of a strong acid in aqueous solution

  • The solution formed is highly acidic due to the high concentration of the H+/H3O+ ions
  • Since the pH depends on the concentration of H+/H3O+ ions, the pH can be calculated if the concentration of the strong acid is known
    • pH = -log10[H+ (aq)]
    • [H+ (aq)] = concentration of H+ / H3O+ ions
    • pH is the negative log of the concentration of H+ / H3O+ ions and can be calculated if the concentration of the strong acid is known using the stoichiometry of the reaction

Weak acids

  • A weak acid is an acid that partially (or incompletely) dissociates in aqueous solutions
    • E.g. most organic acids (ethanoic acid), HCN (hydrocyanic acid), H2S (hydrogen sulfide) and H2CO3 (carbonic acid)
    • The position of the equilibrium is more towards the left and an equilibrium is established

 Diagram to show the dissociation of a weak acid

Diagram showing how weak acids partially dissociate

The diagram shows the partial dissociation of a weak acid in aqueous solution

  • The solution is less acidic due to the lower concentration of H+ / H3O+ ions

Acid & Equilibrium Position Table

  Strong Acids Weak Acid
Position of equilibrium Right Left
Dissociation Completely (→) Partially (rightwards harpoon over leftwards harpoon)
H+ concentration High Low
pH Use [strong acid] to calculate pH Use Ka to find [H+]
Examples

HCl

HNO3

H2SO4 (first ionisation)

Organic acids (ethanoic acid)

HCN

H2S

H2CO3

  • The strength of a Brønsted-Lowry acid depends on the ease with which it dissociates to release H+ ions
    • This depends upon the strength of the bond that has to be broken to release H+
    • For example, for hydrogen halides, the size of the halogen atom increases in size going down Group 17 which increases the length of the H–X bond
    • As longer bonds are weaker they need less energy to break 
    • The acid strength of the hydrogen halides increases down Group 17
      • HF < HCl < HBr < HI

Strong bases

  • A strong base is a base that dissociates almost completely in aqueous solutions

    • E.g. group 1 metal hydroxides such as NaOH (sodium hydroxide)

    • The position of the equilibrium is so far over to the right that you can represent the reaction as an irreversible reaction

 Diagram to show the dissociation of a strong baseDiagram showing how strong bases dissociate

The diagram shows the complete dissociation of a strong base in aqueous solution

  • The solution formed is highly basic due to the high concentration of the OH ions

Weak bases

  • A weak base is a base that partially (or incompletely) dissociates in aqueous solutions
    • NH3 (ammonia), amines and some hydroxides of transition metals
    • The position of the equilibrium is more to the left and an equilibrium is established

 Diagram to show the dissociation of a weak base

Diagram showing how weak bases partially dissociate

The diagram shows the partial dissociation of a weak base in aqueous solution

  •  The solution is less basic due to the lower concentration of OH ions

Base & Equilibrium Position Table

  Strong Base Weak Base
Position of equilibrium Right Left
Dissociation Completely (→) Partially (rightwards harpoon over leftwards harpoon)
OH concentration High Low
Examples

Group 1 metal hydroxides

NH3

Amines

Some transition metal hydroxides

Strength of conjugate acids and bases

  • The conjugate base of HCl is the chloride ion, Cl,
  • However, since the reverse reaction is virtually non-existent the chloride ion must be a very weak conjugate base

HCl (g) → H+ (aq)  +   Cl– (aq)

acid                          conjugate base

  • In general, strong acids produce weak conjugate bases and weak acids produce strong conjugate bases
  • A strong base is also fully ionised and is a good proton acceptor
  • For example, the hydroxide ion is a strong base and readily accepts protons:

   OH– (aq) +  H+ (aq)  ⇌  H2O (l)

  • The conjugate acid of the hydroxide ion is water, which is a weak conjugate acid
  • In general strong bases produce weak conjugate acids

Examiner Tip

  • Hydrogen ions in aqueous solutions can be written as either as H3O+ or as H+
    • However, if H3O+ is used, H2O should be included in the chemical equation:

HCl (g) → H+ (aq) + Cl- (aq)  OR HCl (g) + H2O (l) → H3O+ (aq) + Cl- (aq) 

  • Some acids contain two replaceable protons (called 'dibasic')
    • For example, H2SO4 (sulfuric acid) has two ionisations
      • H2SO4 acts as a strong acid: H2SO4 → H+ + SO4-
      • HSO4- acts as a weak acid: HSO4- ⇌ H+ + SO42-
      • The second ionisation is only partial which is why the concentration of 1 mol dm-3 sulfuric acid is not 2 mol dm-3 in H+ ions
  • Also, don't forget that the terms strong and weak acids and bases are related to the degree of dissociation and not the concentration
    • The appropriate terms to use when describing concentration are dilute and concentrated

How to distinguish between strong and weak acid

  • Strong and weak acids can be distinguished from each other by their:
    • pH value (using a pH meter or universal indicator)
    • Electrical conductivity
    • Reactivity

pH value

  • An acid dissociates into H+ in solution according to

HA → H+ + A-

pH value of a Strong Acid & Weak Acid Table

Acid pH of 0.1 mol dm-3 solution
HCl (strong) 1
CH3COOH (weak) 2.9

  • The stronger the acid, the greater the concentration of H+ and therefore the lower the pH

Electrical conductivity

  • Since a stronger acid has a higher concentration of H+ it conducts electricity better
  • Stronger acids therefore have a greater electrical conductivity
  • The electrical conductivity can be determined by using a conductivity meter
  • Like the pH meter, the conductivity meter is connected to an electrode
  • The conductivity of the solution can be read off the meter

Diagram to show how to measure the electrical conductivity of an acid

Diagram to show how to measure the electrical conductivity of an acid

A digital conductivity meter measures the electrical conductivity of a solution using an electrode

Reactivity

  • Strong and weak acids of the same concentrations react differently with reactive metals
  • This is because the concentration of H+ is greater in strong acids compared to weak acids
  • The greater H+ concentration means that more H2 gas is produced in a shorter time

Diagram to show how a strong acid reacts with magnesium

Diagram to show how a strong acid reacts with magnesium

The diagram shows the reaction of 0.1 mol dm-3 of a strong acid (HCl) with Mg. The reaction produces a lot of bubbles and hydrogen gas due to the high concentration of H+ present in solution

Diagram to show how a weak acid reacts with magnesium

Diagram to show how a weak acid reacts with magnesium

The diagram shows the reaction of 0.1 mol dm-3 of a weak acid (CH3COOH) with Mg. The reaction produces fewer bubbles of hydrogen gas due to the lower concentration of H+ present in solution

  • Similar observations would be made in the reaction between strong and weak acids with carbonates and hydrogencarbonates, although the gas given off this time is carbon dioxide
  • With oxides and hydroxides, there may not be a lot of visible changes although it is likely that they would dissolve faster in a strong acid than in a weak acid
  • These reactions are also likely to produce larger enthalpy changes which could be seen in higher temperature rises

Examiner Tip

  • The above-mentioned properties of strong and weak acids depend on their ability to dissociate and form H+ ions
  • Stronger acids dissociate more
    • This means that they produce a greater concentration of H+ ions resulting in:
      • Lower pH values
      • Greater electrical conductivity
      • More vigorous reactions with reactive metals.

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Philippa Platt

Author: Philippa Platt

Expertise: Chemistry

Philippa has worked as a GCSE and A level chemistry teacher and tutor for over thirteen years. She studied chemistry and sport science at Loughborough University graduating in 2007 having also completed her PGCE in science. Throughout her time as a teacher she was incharge of a boarding house for five years and coached many teams in a variety of sports. When not producing resources with the chemistry team, Philippa enjoys being active outside with her young family and is a very keen gardener.