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4. Strong and Weak Bases

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    This page explains the terms strong and weak as applied to bases. As a part of this it defines and explains Kb and pKb. The usual way of comparing the strengths of bases is to see how readily they produce hydroxide ions in solution. This may be because they already contain hydroxide ions, or because they take hydrogen ions from water molecules to produce hydroxide ions.

    Strong bases

    A strong base is something like sodium hydroxide or potassium hydroxide which is fully ionic. You can think of the compound as being 100% split up into metal ions and hydroxide ions in solution.

    Each mole of sodium hydroxide dissolves to give a mole of hydroxide ions in solution.


    Some strong bases like calcium hydroxide aren't very soluble in water. That doesn't matter - what does dissolve is still 100% ionised into calcium ions and hydroxide ions. Calcium hydroxide still counts as a strong base because of that 100% ionisation.

    Working out the pH of a strong base

    Remember that:

    \[pH = -\log_{10} [H^+]\]

    Since pH is a measure of hydrogen ion concentration, how can a solution which contains hydroxide ions have a pH? To understand this, you need to know about the ionic product for water. Wherever there is water, an equilibrium is set up. Using the simplified version of this equilibrium:

    \[ H_2O_{(l)} \rightleftharpoons H^+_{(aq)} + OH^-_{(aq)}\]

    In the presence of extra hydroxide ions from, say, sodium hydroxide, the equilibrium is still there, but the position of equilibrium has been shifted well to the left according to Le Chatelier's Principle. There will be far fewer hydrogen ions than there are in pure water, but there will still be hydrogen ions present. The pH is a measure of the concentration of these.

    An outline of the method of working out the pH of a strong base

    • Work out the concentration of the hydroxide ions.
    • Use Kw to work out the hydrogen ion concentration.
    • Convert the hydrogen ion concentration to a pH.
    Example 1

    What is the pH of 0.500 mol dm-3 sodium hydroxide solution:?


    Because the sodium hydroxide is fully ionic, each mole of it gives that same number of moles of hydroxide ions in solution.

    [OH-] = 0.500 mol dm-3

    Now you use the value of Kw at the temperature of your solution. You normally take this as 1.00 x 10-14 mol2 dm-6.

    [H+] [OH-] = 1.00 x 10-14

    This is true whether the water is pure or not. In this case we have a value for the hydroxide ion concentration. Substituting that gives:

    [H+] x 0.500 = 1.00 x 10-14

    If you solve that for [H+], and then convert it into pH, you get a pH of 13.7.

    Weak bases

    Ammonia is a typical weak base. Ammonia itself obviously doesn't contain hydroxide ions, but it reacts with water to produce ammonium ions and hydroxide ions.

    \[ NH_{3(aq)} + H_2O_{(l)} \rightleftharpoons NH^+_{4(aq)} + OH^-_{(aq)}\]

    However, the reaction is reversible, and at any one time about 99% of the ammonia is still present as ammonia molecules. Only about 1% has actually produced hydroxide ions. A weak base is one which doesn't convert fully into hydroxide ions in solution. When a weak base reacts with water, the position of equilibrium varies from base to base. The further to the left it is, the weaker the base.


    You can get a measure of the position of an equilibrium by writing an equilibrium constant for the reaction. The lower the value for the constant, the more the equilibrium lies to the left. In this case the equilibrium constant is called Kb. This is defined as:

    \[ K_b = \dfrac{[B:H^+][OH^-]}{[B:]}\]

    The relationship between Kb and pKb is exactly the same as all the other "p" terms in this topic:

    \[pK_b = -\log_{10} K_b\]

    The table shows some values for \(K_b\) and \(pK_b\) for some weak bases.

    base Kb (mol dm-3) pKb
    C6H5NH2 4.17 x 10-10 9.38
    NH3 1.78 x 10-5 4.75
    CH3NH2 4.37 x 10-4 3.36
    CH3CH2NH2 5.37 x 10-4 3.27

    As you go down the table, the value of Kb is increasing. That means that the bases are getting stronger. As Kb gets bigger, pKb gets smaller. The lower the value of pKb, the stronger the base. This is exactly in line with the corresponding term for acids, pKa - the smaller the value, the stronger the acid.

    This page titled 4. Strong and Weak Bases is shared under a CC BY-NC 4.0 license and was authored, remixed, and/or curated by Jim Clark.

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