2.8 : Acid–Base Equilibria: Activity-Based Definition of pH

The definition of the pH of a solution as the negative logarithm of the hydrogen ion concentration is valid only for an ideal solution.

In practice, the pH measurement considers the negative logarithm of the hydrogen ion activity rather than concentration.

So, the pH can be more accurately redefined as the negative logarithm of the product of the hydrogen ion concentration and its activity coefficient.

In the case of pure water at 25 degrees C, the extremely low ionic strength suggests that the activity coefficients of the ions are close to one.

However, adding a salt like potassium chloride to the water increases the ionic strength of the solution, thus decreasing the activity coefficients.

It follows here that the hydrogen ion activity is slightly increased, corresponding to a decrease in the pH of the solution.

Notably, the addition of potassium chloride causes a negligible change in pH but a significant increase in the hydrogen ion concentration.

For an ideal solution, the pH is defined as the negative logarithm of the hydrogen ion concentration. For a non-ideal solution, an accurate measurement of the pH must consider the negative logarithm of the hydrogen ion activity rather than concentration. In such a solution, the pH can be more accurately defined as the negative logarithm of a product of the hydrogen ion concentration and its activity coefficient.

In solutions of very low ionic strength—for example, pure water—the activity coefficient of the hydrogen ion is close to one when the ionic strength of the solution increases due to the addition of an electrolyte that does not donate or accept a proton. This results in a slight decrease in the pH of the solution. In other words, the addition of an electrolyte increases the hydrogen ion activity, or the effective hydrogen ion concentration in the solution, which decreases the pH of the solution.

Tags

Acid base Equilibria PH Definition Hydrogen Ion Concentration Hydrogen Ion Activity Non ideal Solution Activity Coefficient Ionic Strength Electrolyte Effects Effective Hydrogen Ion Concentration

From Chapter 2:

article

Now Playing

2.8 : Acid–Base Equilibria: Activity-Based Definition of pH

Chemical Equilibria

515 Views

article

2.1 : Ionic Strength: Overview

Chemical Equilibria

1.2K Views

article

2.2 : Ionic Strength: Effects on Chemical Equilibria

Chemical Equilibria

1.3K Views

article

2.3 : Thermodynamics: Chemical Potential and Activity

Chemical Equilibria

811 Views

article

2.4 : Thermodynamics: Activity Coefficient

Chemical Equilibria

1.2K Views

article

2.5 : Chemical Equilibria: Redefining Equilibrium Constant

Chemical Equilibria

494 Views

article

2.6 : Factors Affecting Activity Coefficient

Chemical Equilibria

683 Views

article

2.7 : Chemical Equilibria: Systematic Approach to Equilibrium Calculations

Chemical Equilibria

597 Views

article

2.9 : Ladder Diagrams: Acid–Base Equilibria

Chemical Equilibria

423 Views

article

2.10 : Ladder Diagrams: Redox Equilibria

Chemical Equilibria

408 Views

article

2.11 : Ladder Diagrams: Complexation Equilibria

Chemical Equilibria

293 Views

article

2.12 : Solubility Equilibria: Overview

Chemical Equilibria

560 Views

article

2.13 : Solubility Equilibria: Ionic Product of Water

Chemical Equilibria

910 Views

article

2.14 : Complexation Equilibria: Overview

Chemical Equilibria

577 Views

article

2.15 : Complexation Equilibria: The Chelate Effect

Chemical Equilibria

406 Views

See More

Copyright © 2025 MyJoVE Corporation. All rights reserved