From a Chemist's point of view, there are two different concepts involved in this seemingly harmless "neutral pH" expression. These two different concepts are:
- neutral
- pH
A solution is neutral if the concentration of hydrogen ions, [H+], is equal to the concentration of hydroxide ions, [OH-].
Chemists often use square brackets to denote concentration, the concentration of hydrogen ions can be written as [H+] and the concentration of hydroxide ions can be written as [OH-].
So, for a neutral solution:
[H+] = [OH-] = neutral solution
Pure water is an excellent example of a neutral substance.
Some of the water molecules, actually very few of them, dissociate to form hydrogen ions and hydroxide ions:
| H2O | 
| H+ + OH- |
Therefore, pure water is always neutral!
The pH of a solution is a measure of the hydrogen ion concentration in the solution. pH can be defined as:
pH = -log10[H+]
This equation can be used to calculate the pH of our neutral water, but only if we know the concentration of hydrogen ions in the water.
The concentration of hydrogen ions in water is not constant!
The concentration of hydrogen ions in water depends on the temperature of the water!
The dissociation of water molecules requires energy:
The dissociation of water molecules requires energy:
| H2O + energy |
| H+ + OH- |
If you take energy away from the system by cooling it, then fewer water molecules dissociate, the concentration of hydrogen ions decreases and the concentration of hydroxide ions also decreases.
If we were to measure the concentration of hydrogen ions in pure water at various temperatures, we would find the following values:
| Water temperature | [H+] x 10−7 M | pH |
|---|---|---|
| 0°C | 0.32 | 7.50 |
| 10°C | 0.55 | 7.26 |
| 18°C | 0.84 | 7.08 |
| 25°C | 1.10 | 6.96 |
| 30°C | 1.34 | 6.87 |
| 50°C | 2.82 | 6.55 |
| 60°C | 3.55 | 6.46 |
| 70°C | 4.60 | 6.34 |
| 80°C | 5.92 | 6.23 |
| 90°C | 7.28 | 6.14 |
| 100°C | 8.54 | 6.07 |
So what is the pH of water?
The pH of water is dependent on the temperature of the water.
Water is neutral for every value of pH because the concentration of hydrogen ions is always equal to the concentration of the hydroxide ions.
We can ONLY talk about the pH of water IF we state the temperature of the water.
For example, we can talk about water having a pH of approximately 7 at 25oC, or we could say that the pH of water is approximately 6 at 100oC.
Pure water is always neutral.
Pure water is neutral at 25oC.
Pure water is neutral at 100oC.
As Chemistry students, what we can't say is that water has a pH of 7, or that a neutral aqueous solution has a particular pH, unless we state the temperature of the system.
Further Reading:
Definitions of Acids and Bases
pH
Dissociation Constant for Water
Suggested Study Questions:
- Plot a graph of temperature versus concentration of hydrogen ions in water. Describe the shape of the line, and write a generalization that links hydrogen ion concentration and temperature.
- Plot a graph of temperature versus pH of water. Describe the shape of the line and write a generalization linking the temperature of water and its pH.
- Use your graph to find the pH of water at:
- 12oC
- 22oC
- 32oC
- Construct a table giving the concentration of hydroxide ions in water at each of the temperatures shown above.
- Plot a graph of temperature versus concentration of hydroxide ions in water. Describe the shape of the line, and write a generalization linking hydroxide ion concentration in water and temperature.
- Use your graph to find the concentration of hydroxide ions in water at:
- 12oC
- 22oC
- 32oC
- Explain why water is neutral at all temperatures.
- Explain why the pH of water varies with temperature.
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