Fundamental aquatic chemistry concepts may be introduced in general chemistry classes by computing ionization fractions and buffer intensity of aqueous phase carbonate systems. This Excel spreadsheet may used to build graphic presentations of a titration curve, distribution diagram, and buffer intensity as a function of pH. Accompanying activities are designed to enhance the concepts of acid-base equilibrium through exploring the relationship between pK_a /pK_b, pH of the solution, ionization fractions and buffer intensity, and to exercise students’ graphing skills.

Preliminary experiment.

A preliminary experiment was conducted to create a titration curve of the carbonate system; 0.1 M Na₂CO₃ solution was titrated with 0.1 M HCl. Using Excel, students plotted volume of HCl added as a function of pH. While this is not the customary method of graphing a titration curve, it is necessary for comparison with graphs produced in the activities that follow.

Activity I: Ionization fraction (a) and distribution diagram

Ionization fraction (a) is the relative amount of each species as a fraction of overall analytical concentration (C_T). For the carbonate system, there are three ionization fractions: carbonic acid (a₀), bicarbonate (a₁), and carbonate (a₂). If ionic strength effects are neglected, the ionization fraction of each carbonic species can be worked out to the following, using the equilibria expressions for K_a1 and K_a2. (The derivation is worked out more completely in the full documentation.)

These three equations show the relationship between the ionization fraction of each carbonic species and the pH of the solution. A plot of these ionization fractions vs pH was also made using Excel.

Activity II:Graphic representation of buffer intensity

Buffer intensity (β) is defined as the ability to keep the solution pH steady. In mathematical expression, the buffer intensity is expressed as following:

(1)

where C_B and C_A are the added strong base and acid, respectively in moles/liter.

Because the titration curve (figure below, top graph) was plotted with pH on the abscissa, and because C is directly proportional to the volume of added 0.1M HCl, the buffer intensity is proportional to the negative slope of the titration curve.

Due to mathematical complexity, the well-known approximate numerical expression (6) of buffering intensity was derived in class and used to calculate the buffer intensity of the carbonate system.

β was then plotted vs pH.

Screenshot of Excel spreadsheet with a graphic representation for 0.1 M Na₂CO₃ solution. The titration curve (concentration vs pH) is plotted on the top graph, ionization fraction and buffer intensity vs pH on the bottom. Vertical lines show the correlations of maximal buffering intensity at pH = pK_a1or pK_a2 , and minimal intensity when any single carbonic species is dominant in the solution.

Activity III: Analysis of the Graphs

To clearly understand the relationship between the titration curve, ionization fraction, and buffer intensity, the graphs of all these were brought into a same worksheet for comparison (Figure 2). (Note that all graphs have same pH scale on the abscissa for convenient analysis.)

The combined graphs show clearly that when the pH = pK_a1 or pK_a2, buffer intensity reaches its maximum, while the intensity is at it minimum when any single carbonic species is dominant.

This spreadsheet can be used for other acid-base reactions as well, and a comparison among the plots of different systems under similar conditions would be useful for comparing their properties.

Literature Cited

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6. Snoeyink, V. L.; Jenkins D. Water Chemistry; John Wiley & Sons: New York, 1980; 149–153.