9.3 pH

The pH scale (ESCPC)

The concentration of specific ions in solution determines whether the solution is acidic or basic. Acids and bases can be described as substances that either increase or decrease the concentration of hydrogen (\(\text{H}^{+}\)) or hydronium (\(\text{H}_{3}\text{O}^{+}\)) ions in a solution. An acid increases the hydrogen ion concentration in a solution, while a base decreases the hydrogen ion concentration.

pH is used to measure the concentration of \(\text{H}^{+}\) ions (\([\text{H}^{+}]\)) and therefore, whether a substance is acidic or basic (alkaline). Solutions with a pH of less than seven are acidic, while those with a pH greater than seven are basic (alkaline). The pH scale ranges from \(\text{0}\) to \(\text{14}\) and a pH of \(\text{7}\) is considered neutral.

The universal indicator changes colour from \(\color{red}{\textbf{red}}\) in \(\color{red}{\textbf{strongly acidic}}\) solutions through to \(\color{purple}{\textbf{purple}}\) in \(\color{purple}{\textbf{strongly basic}}\) solutions.

pH

pH is a measure of the acidity or alkalinity of a solution.

At the beginning of the chapter we mentioned that we encounter many examples of acids and bases in our day-to-day lives. The pH of solutions of some household acids and bases are given in Table 9.6.

pH calculations (ESCPD)

pH can be calculated using the following equation:

pH = -log[\(\text{H}^{+}\)]

[\(\text{H}^{+}\)] and [\(\text{H}_{3}\text{O}^{+}\)] can be substituted for one another:

pH = -log[\(\text{H}_{3}\text{O}^{+}\)]

The brackets in the above equation are used to show concentration in \(\text{mol·dm$^{-3}$}\).

Understanding pH is very important. In living organisms, it is necessary to maintain a constant pH in the optimal range for that organism, so that chemical reactions can occur.

pH	\(\text{1}\)	\(\text{6}\)	\(\text{7}\)	\(\text{8}\)	\(\text{13}\)
\([\text{H}^{+}]\)	\(\text{1} \times \text{10}^{-\text{1}}\)	\(\text{1} \times \text{10}^{-\text{6}}\)	\(\text{1} \times \text{10}^{-\text{7}}\)	\(\text{1} \times \text{10}^{-\text{8}}\)	\(\text{1} \times \text{10}^{-\text{13}}\)
\([\text{OH}^{-}]\)	\(\text{1} \times \text{10}^{-\text{13}}\)	\(\text{1} \times \text{10}^{-\text{8}}\)	\(\text{1} \times \text{10}^{-\text{7}}\)	\(\text{1} \times \text{10}^{-\text{6}}\)	\(\text{1} \times \text{10}^{-\text{1}}\)
Solution	\(\color{red}{\textbf{strongly acidic}}\)	\(\color{red}{\text{weakly acidic}}\)	neutral	\(\color{blue}{\text{weakly basic}}\)	\(\color{blue}{\textbf{strongly basic}}\)

Table 9.7: The concentration of \([\text{H}^{+}]\) and \([\text{OH}^{-}]\) ions in solutions with different pH.

Litmus paper can be used as a pH indicator. It is sold in strips. Purple litmus paper will become red in acidic conditions and blue in basic conditions. Blue litmus paper is used to detect acidic conditions, while red litmus paper is used to detect basic conditions.

In agriculture, it is important for farmers to know the pH of their soils so that they are able to plant the right kinds of crops. The pH of soils can vary depending on a number of factors, such as rainwater, the kinds of rocks and materials from which the soil was formed and also human influences such as pollution and fertilisers. The pH of rain water can also vary, and this too has an effect on agriculture, buildings, water courses, animals and plants. Rainwater is naturally acidic because carbon dioxide in the atmosphere combines with water to form carbonic acid. Unpolluted rainwater has a pH of approximately \(\text{5,6}\). However, human activities can alter the acidity of rain and this can cause serious problems such as acid rain.

\(K_{w}\) (ESCPF)

Water ionises to a very small extent:

\(\text{H}_{2}\text{O}(\text{l}) + \text{H}_{2}\text{O}(\text{l})\) \(\rightleftharpoons\) \(\text{H}_{3}\text{O}^{+}(\text{aq}) + \text{OH}^{-}(\text{aq})\)

This type of reaction (the transfer of a proton between identical molecules) is known as auto-protolysis. This reaction is also known as the auto-ionisation of water and the ions formed are a conjugate acid and base pair of water:

Auto-protolysis and auto-ionisation of water

Auto-protolysis is the transfer of a proton between two of the same molecules. The auto-ionisation of water is one example of auto-protolysis.

\(\text{K}_{\text{w}}\) is the equilibrium constant for this process:

\(\text{K}_{\text{w}}\) = \([\text{H}_{3}\text{O}^{+}][\text{OH}^{-}]\)

At \(\text{25}\) \(\text{℃}\): \([\text{H}_{3}\text{O}^{+}]\) = [\(\text{H}^{+}\)] = \(\text{1} \times \text{10}^{-\text{7}}\), therefore:

\(\text{K}_{\text{w}}\) = \(\text{1} \times \text{10}^{-\text{14}}\) at \(\text{25}\) \(\text{℃}\)

Salt hydrolysis (ESCPG)

Does neutralisation mean that the pH of the solution is \(\text{7}\)? No. At the equivalence point of a reaction, the pH of the solution need not be \(\text{7}\). This is because of the interaction of the salt (formed by the reaction) and water.

At the equivalence point of an acid-base neutralisation reaction there is salt and water. The ions of water interact with the salt present and form a small quantity of excess hydronium ions (\(\text{H}_{3}\text{O}^{+}\)) or hydroxide ions (\(\text{OH}^{-}\)). This leads to pH values that are not equal to \(\text{7}\).

A simple rule for determining the likely pH of a solution is as follows:

• A \(\color{red}{\textbf{strong }\text{acid}} + \color{blue}{\textbf{strong }\text{base}}\) form a \(\color{darkgreen}{\textbf{neutral}}\) salt and water \(\color{darkgreen}{\textbf{solution}}\):

  \(\to\) pH = \(\text{7}\).

  \(\color{red}{\text{H}_{2}{\text{SO}}_{4}{\text{(aq)}}} + 2\color{blue}{\text{NaOH(s)}} \to \color{darkgreen}{\textbf{Na}_{2}{\textbf{SO}}_{4}{\textbf{(aq)}}} + 2\color{darkgreen}{\text{H}_{2}{\text{O(ℓ)}}}\)

• A \(\color{red}{\textbf{weak }\text{acid}} + \color{blue}{\textbf{strong }\text{base}}\) form a \(\color{blue}{\textbf{weak basic}}\) salt and water \(\color{blue}{\textbf{solution}}\):

  \(\to\) pH = approximately \(\text{9}\).

  \(\color{red}{\text{HF(aq)}} + \color{blue}{\text{NaOH(s)}} \to \color{blue}{\textbf{NaF(aq)}} + \color{blue}{\text{H}_{2}{\text{O(ℓ)}}}\)

• A \(\color{red}{\textbf{strong }\text{acid}} + \color{blue}{\textbf{weak }\text{base}}\) form a \(\color{red}{\textbf{weak acidic}}\) salt \(\color{red}{\textbf{solution}}\):

  \(\to\) pH = approximately \(\text{5}\).

  \(\color{red}{\text{H}_{2}{\text{SO}}_{4}{\text{(aq)}}} + 2\color{blue}{\text{NH}_{3}{\text{(ℓ)}}} \to \color{red}{\textbf{(NH}_{4}{\textbf{)}}_{2}{\textbf{SO}}_{4}{\textbf{(aq)}}}\)

Indicators (ESCPH)

A titration is a process for determining, with precision, the concentration of a solution with unknown concentration. The theory behind titrations will be discussed later in this chapter. An indicator is used to show the scientist carrying out the reaction exactly when the reaction has reached completion.

Indicators are chemical compounds that change colour depending on whether they are in an acidic or a basic solution. A titration requires an indicator that will respond to the change in pH with a sensitive and quick colour change. Typical indicators used in titrations are given in Table 9.9.

Indicators change colour (Figure 9.3) according to where the \(\text{H}\) is:

So, when an acid is added to aqueous bromothymol blue there will be extra \(\text{H}^{+}\) ions. The equilibrium will shift (remember le Chatalier's principle) to decrease the number of \(\text{H}^{+}\) ions. That is, to the left. If sufficient acid is added, the entire solution will become acidic. This means there will be more HBromothymol blue than bromothymol blue\(^{-}\) and the solution will become yellow.