Acid - Base indicators (also known as pH indicators) are substances which change colour
with pH. They are divalent weak acids or bases, involved in protolytic water acid-base equilibrium and form two type coloured ions as Brensted-Lowry protolytical pairs.
Consider an indicator which is a weak acid, with the formula H2In . At equilibrium, the
following equilibrium equation is established with its conjugate base In2- :
H2In (aq)
+ 2 H2O (l)
2 H3O+ (aq) +
In2- (aq)
acid
conjugate base
(colour A)
(colour B)
The acid and its conjugate base have different colours. At low pH values the
concentration of H3O+ is high and so the equilibrium position lies
to the left. The equilibrium solution has the colour A. At high pH values, the
concentration of H3O+ is low - the equilibrium position thus lies to
the right and the equilibrium solution has colour B.
Phenolphthalein is an example of an indicator which establishes this type of equilibrium
in aqueous solution:
Kln is known as the indicator dissociation constant.
The colour of the indicator turns from colour A to colour B or vice versa at its turning
point. At this point:
[H2In] =[In2-]
So from equation:
KIn = [H3O+]2 = 10-18.8
; pKIn / 2 = 9.4 = pH = -log{SQRT( [H3O+]2
)}
The pH of the solution at its turning point is called the pKln and is the pH at which half of the indicator is in its acid form and the other half in the form of its conjugate base.
At a low pH, a weak acid indicator is almost entirely in the [H2In] form,
the colour of which predominates. As the pH increases - the intensity of the colour of [H2In]
decreases and the equilibrium is pushed to the right. Therefore the intensity of the
colour of [In-] increases. Physiological condition for certainly distinct
colour is assumed at ratio for conjugated base form:
[In2-] / [H2In]
= 10 ; and for acid coloured form : [In2-] / [H2In]
= 1 / 10 = 0.1
-KIn = ([H3O+]2�[In2-]
/ [H2In])eq = 10-18.8 *10 ; +KIn =
([H3O+]2�[In2-] / [H2In])eq
= 10-18.8 *0.1
-pHIn = 17.8 / 2 = 8.9
; +pHIn = 19.8 / 2 = 9.9
An indicator is most effective if the colour change is distinct and over a low pH
range. For most indicators the range is within �0.5 of the pKln value: -
please see the table below for examples, to the right is a model of the acid form of each
indicator - with the colour of the solution at the turning point. Number 2
of involved hydrogen protons H+ in equilibrium .
Indicator Return to index |
Colour | pH colour turning point |
pH range | |
Acid | Base | pKln / n | -pH<pKln>+pH | |
Thymol Blue - 1st change | red | yellow | 1.7 | 0.7 - 2.7 |
Methyl Orange | red | yellow | 3.7 | 3.2 - 4.2 |
Bromocresol Green | yellow | blue | 4.7 | 4.2 - 5.2 |
Methyl Red | yellow | red | 5.1 | 4.6 - 5.6 |
Bromothymol Blue | yellow | blue | 7.0 | 6.5 - 7.5 |
Phenol Red | yellow | red | 7.9 | 7.4 - 8.4 |
Thymol Blue - 2nd change | yellow | blue | 8.9 | 7.9 - 9.9 |
Phenolphthalein | colourless | pink | 9.4 | 8.9 - 9.9 |
A Universal Indicator is a mixture of indicators which give a gradual change in colour over a wide pH range - the pH of a solution can be approximately identified when a few drops of universal indicator are mixed with the solution.
Indicators are used in titration solutions to signal the completion of the acid-base reaction.