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Figure 3-1. Schematic diagram showing the frequency of pH values in natural waters. The major controls for each pH range are indicated on the diagram.

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Presentation on theme: "Figure 3-1. Schematic diagram showing the frequency of pH values in natural waters. The major controls for each pH range are indicated on the diagram."— Presentation transcript:

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4 Figure 3-1. Schematic diagram showing the frequency of pH values in natural waters. The major controls for each pH range are indicated on the diagram. After Langmuir (1997).

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6 Figure 3-2. Relative activity of various carbonate species as a function of pH.

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9 Figure 3-3. Schematic representation of an acid-base titration curve for a strong acid (base). The inflection point is at pH = 7.0, where all the excess H + (acid) or OH - (base) has been consumed. Titrant is a base for an acidity determination; an acid for an alkalinity determination

10 Figure 3-4. Schematic acidity titration curve for a solution that contains a strong acid and carbonic acid. See text for details.

11 Figure 3-5. Variations in buffer capacity as a function of pH for water. Only at very low and very high pH values is water an important buffer.

12 Figure 3-6. Variations in buffering capacity as a function of pH for water and acetic acid when C A = 1 mol.

13 Figure 3-7. Variations in buffering capacity as a function of pH for the system carbonic acid-water when C A = 1 x 10 - 3 mol L -1.

14 Figure 3-8. Variations in buffering capacity as a function of pH for the calcite-carbonic acid system. C T = 1 x 10 -3 mol L -1.

15 Figure 3-9. Summary of buffering reactions for natural waters containing carbonic acid and/or in contact with various minerals. Note the importance of the carbonate and clay minerals for buffering acid additions to natural waters.

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17 Figure 3-C1-1. Variations in pH, HCO 3 -, and P CO 2 for two groundwater and one stream system. Arrows indicate the direction of groundwater flow. From Langmuir (1997).

18 Figure 3-C2-1. The relationship between pH and log[HCO 3 - ] and log[Ca 2+ ]. From Li and Misawa (1994).

19 Figure 3-C3-1. Trend in Ca concentration predicted by the reaction path model. Dashed lines show simple mixing for fluids with different amounts of added Ca. Filled squares represent individual water samples. The reaction pathway is shown by the heavy line. In leg 1, Ca is added by dissolution of limestone. In leg 2, Ca concentrations change only by simple dilution. In leg 1, 2.5 kg of uncontaminated water and 250 mg of Ca are added to the solution. In leg 2, 12.5 kg of uncontaminated water is added. From Berger et al. (2000).

20 Figure 3-C4-1. Water-rock reactions as a function of time. Initial input is 1 mol of CO 2 into 1 kg of formation water. (a) Variation in amounts of aqueous species and (b) minerals for the Nisku carbonated aquifer. (c) Variation in amounts of aqueous species and (d) minerals for the Glauconitic Sandstone aquifer. From Gunter et al. (2000).

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