15.4 : pH Scale

The concentration of hydronium ions in an aqueous solution is usually written with negative exponents and can be as small as 1 × 10⁻¹⁴ M. The pH scale was developed by chemist Soren Sorenson in 1909 as a more convenient way to quickly compare the acidity of different solutions.

The pH of a solution is the negative logarithm of its hydronium ion concentration. For example, a solution with 1 × 10⁻⁵ M hydronium concentration has a pH of 5. The greater the hydronium ion concentration of a solution, the lower its pH.

As pH is expressed on a logarithmic scale, a single-unit change corresponds to a 10-fold increase or decrease of the hydronium ion concentration. A solution with a pH of 3 will have ten times more hydronium ions than a solution with a pH 4 and one hundred times more than a solution with a pH of 5.

An acidic solution has a higher concentration of hydronium ions than hydroxide ions and a pH less than 7, whereas a basic solution has a lower concentration of hydronium ions than hydroxide ions and a pH greater than 7.

A neutral solution with an equal concentration of hydronium and hydroxide ions has a pH of 7.

The concentration of hydroxide ions can also be expressed as pOH. pOH is the negative logarithm of the hydroxide ion concentration. The higher the hydroxide ion concentration, the lower its pOH value.

A pH or pOH value of an aqueous solution ranges from 0 – 14. This is because K_W, the equilibrium constant for the autoionization of water, is equal to 1 × 10⁻¹⁴.

Taking the negative log of both sides of the equation results in an equation where pK_W is equal to the sum of pH and pOH. Since the negative log of 1 × 10⁻¹⁴ is 14, the sum of the pH and pOH of an aqueous solution will always be 14. This can be used to determine the pH value when the pOH value is known and vice versa.

For example, a solution with a pOH of 10 has a pH of 4.

Hydronium and hydroxide ions are present both in pure water and in all aqueous solutions, and their concentrations are inversely proportional as determined by the ion product of water (K_w). The concentrations of these ions in a solution are often critical determinants of the solution’s properties and the chemical behaviors of its other solutes. Two different solutions can differ in their hydronium or hydroxide ion concentrations by a million, billion, or even trillion times. A common means of expressing quantities that may span many orders of magnitude is to use a logarithmic scale. The pH of a solution is therefore defined as shown here, where [H₃O⁺] is the molar concentration of hydronium ion in the solution:

Chemical structure of paracetamol molecule, illustrating atomic bonds, planar conformation.

Rearranging this equation to isolate the hydronium ion molarity yields the equivalent expression:

Thermal cycle diagram showing Brayton cycle stages and state points labeled in flow process chart.

Likewise, the hydroxide ion molarity may be expressed as a p-function or pOH:

Static equilibrium diagram with ΣFx=0 and MA=0; force vectors, beam, pivot point shown.

or

Vapor-liquid equilibrium diagram; isotherm, pressure-composition; distillation analysis.

Finally, the relation between these two ion concentration expressed as p-functions is easily derived from the K_W expression:

Chromatography system diagram; protein purification process; shows elution column and analyte flow.

At 25 °C, the value of K_W is 1.0 × 10⁻¹⁴, and so:

Static equilibrium equations diagram with ΣFx=0, ΣFy=0, MA=0 for educational research use.

The hydronium ion molarity in pure water (or any neutral solution) is 1.0 × 10⁻⁷M at 25 °C. The pH and pOH of a neutral solution at this temperature are therefore:

Static equilibrium equations diagram with forces ΣFx=0, ΣFy=0, moment MA=0 for analysis.

And so, at this temperature, acidic solutions are those with hydronium ion molarities greater than 1.0 × 10⁻⁷M and hydroxide ion molarities less than 1.0 × 10⁻⁷ M (corresponding to pH values less than 7.00 and pOH values greater than 7.00). Basic solutions are those with hydronium ion molarities less than 1.0 × 10⁻⁷ M and hydroxide ion molarities greater than 1.0 × 10⁻⁷ M (corresponding to pH values greater than 7.00 and pOH values less than 7.00).

Since the autoionization constant K_W is temperature dependent, these correlations between pH values and the acidic/neutral/basic adjectives will be different at temperatures other than 25 °C. For example, the hydronium molarity of pure water at 80°C is 4.9 × 10⁻⁷ M, which corresponds to pH and pOH values of:

Chomsky hierarchy diagram illustrating formal grammar classification and language hierarchy.

At this temperature, neutral solutions exhibit pH = pOH = 6.31, acidic solutions exhibit pH less than 6.31 and pOH greater than 6.31, whereas basic solutions exhibit pH greater than 6.31 and pOH less than 6.31. This distinction can be important when studying certain processes that occur at other temperatures, such as enzyme reactions in warm-blooded organisms at a temperature around 36 – 40 °C. Unless otherwise noted, references to pH values are presumed to be those at 25 °C.

This text is adapted from Openstax, Chemistry 2e, Section 14.2: pH and pOH.

Tags

PH Scale Hydronium Ions Aqueous Solution Negative Exponents Chemist Soren Sorenson Acidity Logarithm Concentration Acidic Solution Basic Solution Hydroxide Ions Neutral Solution POH Value Autoionization Of Water

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