Theories of acid base indicators
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The document discusses theories of acid-base indicators and their use. It describes the Ostwald theory which states that indicators exist in different colored acid and conjugate base forms and reach equilibrium based on solution pH. The resonance theory indicates color changes are due to tautomeric molecular structure changes. A table lists common indicators and their corresponding pH ranges and color changes, such as phenolphthalein changing from colorless to pink to red from pH 8.3 to 10.
![Email: shah.sapan@rediffmail.com
• Thus the limit of visible color change will be represented
by the introduction of the term log10 for log[In-]/[HIn] in
the above expression so that
• The average color change interval of an indicator is,
therefore, about two pH units.
• The observed color changes within the indicator range
are seen as gradual change of tint or shade which ranges
from one extreme color to the other.
• The shade of color is independent of the amount of
indicator present, but the use of too much indicator
should be avoided as slight changes are then more
difficult to detect.](https://image.slidesharecdn.com/theoriesofacidbaseindicators-191009071232/85/Theories-of-acid-base-indicators-12-320.jpg)
Theories of acid base indicators
- 1. Email: shah.sapan@rediffmail.com Theories of acid base indicators Sapan K. Shah Assistant Professor Priyadarshini J. L. College of Pharmacy, Nagpur-440016
- 2. Email: shah.sapan@rediffmail.com Theories of neutralization (Acid base) Indicators 1. Ostwald Theory 2. Resonance Theory (Quinonoid Theory)
- 3. Email: shah.sapan@rediffmail.com 1) Ostwald Theory • Indicators are weak acids or weak bases which have different colors in their conjugate base and acid forms (two color indicators); • Others are one color indicators, and have one form colored with a colorless conjugate form. • Most indicators in common use are intensely colored, and can be used in dilute solution in such small quantities that the acid-base equilibrium which is under examination is not disturbed by the addition of the indicator.
- 4. Email: shah.sapan@rediffmail.com • As weak acids or weak bases, they are able to reach instantaneous equilibrium with the system, and • the color of the solution will range between the extreme colors of the two forms as the proportion of acidic and basic forms automatically adjusts itself to the pH of the solution.
- 5. Email: shah.sapan@rediffmail.com • The following equilibrium will apply for an indicator functioning as weak acid: HIn H+ + In– • In acid solution, the excess of H+ ions will depress the ionization of the indicator. The concentration of In– will be small, and of HIn large, and the color will be that of the unionized form. • Alkali will promote removal of hydrogen ions from the system with an increase in the concentration of the ionized form (In–) so that the solution acquires the ionized color.
- 7. Email: shah.sapan@rediffmail.com • Similarly for an indicator functioning as a weak base, the following equilibrium will apply:
- 8. Email: shah.sapan@rediffmail.com 2) Resonance (Quinonoid) Theory • Although the behavior of indicators can be explained in terms of ionization of weak acids and bases, as above, the equilibrium is actually more complex, • the color changes being brought about by tautomeric changes in the structure of the molecule.
- 9. Email: shah.sapan@rediffmail.com This is illustrated by the behavior of phenolphthalein in solution- The red color in alkaline solution is due to the quinonoid structure, with the resulting increased possibilities for resonance between the various ionic forms.
- 11. Email: shah.sapan@rediffmail.com pH range of indicators(color change interval): • The observed color of a two color indicator is determined by the ratio of the concentrations of ionized and unionized forms. • Observable color changes are, however, limited by the ability of the human eye to detect changes of color in mixtures. • This is particularly difficult where one color predominates and in practice is almost impossible when the ration of the two forms exceeds 10 to 1.
- 12. Email: shah.sapan@rediffmail.com • Thus the limit of visible color change will be represented by the introduction of the term log10 for log[In-]/[HIn] in the above expression so that • The average color change interval of an indicator is, therefore, about two pH units. • The observed color changes within the indicator range are seen as gradual change of tint or shade which ranges from one extreme color to the other. • The shade of color is independent of the amount of indicator present, but the use of too much indicator should be avoided as slight changes are then more difficult to detect.
- 13. Email: shah.sapan@rediffmail.com • With a single color indicator, such as phenolphthalein, the intensity of color is important and not shades difference. • The actual concentration of indicator is therefore significant, and should be carefully controlled. • Since the useful range of an indicator only extends over approximately two pH units, it is essential to have a series of indicators available to cover the complete pH scale.
- 14. Email: shah.sapan@rediffmail.com A list of such indicators in common use, together with their color changes is given in table. Indicator pH range Color changes Phenolphthalein 8.3-10 colorless pink Red Methyl orange 2.9-4.6 Red Orange yellow Methyl red 4.2-6.3 Red Orange Yellow Phenol red 6.8-8.4 Yellow Orange Red Thymolphthalein 9.3-10.5 Colorless Pink Red