Weak Acid pH Calculator

Calculate the pH of a 0.31 M CH3COOH Solution

Use this premium calculator to find the pH of acetic acid solution from concentration and Ka, compare the exact quadratic result with the weak acid approximation, and visualize hydrogen ion concentration with an interactive chart.

Interactive Calculator

Acetic acid concentration, C (M)

Acid dissociation constant, Ka

Calculation method

Reference temperature

Enter values and click Calculate pH to see the full weak acid analysis.

How to calculate the pH of a 0.31 M CH3COOH solution

To calculate the pH of a 0.31 M CH3COOH solution, you need to remember that acetic acid is a weak acid, not a strong acid. That means it does not ionize completely in water. Instead, only a small fraction of the dissolved CH3COOH molecules donate a proton to water, producing hydronium ions and acetate ions. Because pH depends on hydronium concentration, the correct strategy is to use the acid dissociation equilibrium, not a complete dissociation assumption.

The equilibrium reaction is:

CH3COOH(aq) ⇌ H+(aq) + CH3COO-(aq)

At 25°C, the acid dissociation constant for acetic acid is commonly taken as Ka = 1.8 × 10^-5. The starting concentration of acetic acid is 0.31 M. The main objective is to find the equilibrium concentration of H⁺, then convert that value to pH using:

pH = -log10[H+]

Step 1: Set up the ICE table

The standard equilibrium method begins with an ICE table, which stands for Initial, Change, and Equilibrium. Let x represent the amount of CH3COOH that dissociates.

Initial: [CH3COOH] = 0.31, [H⁺] = 0, [CH3COO^–] = 0
Change: [CH3COOH] decreases by x, [H⁺] increases by x, [CH3COO^–] increases by x
Equilibrium: [CH3COOH] = 0.31 – x, [H⁺] = x, [CH3COO^–] = x

Substituting these values into the Ka expression gives:

Ka = [H+][CH3COO-] / [CH3COOH] = x² / (0.31 – x)

Step 2: Solve the equilibrium expression

Plug in the Ka value:

1.8 × 10^-5 = x² / (0.31 – x)

There are two common ways to solve this. The first is the weak acid approximation, where x is assumed to be much smaller than 0.31, so 0.31 – x is treated as 0.31. The second is the exact quadratic solution. For this concentration and Ka, both methods are very close, but the exact method is the most rigorous.

Approximation method

If x is small relative to 0.31, then:

x² / 0.31 = 1.8 × 10^-5

x² = (1.8 × 10^-5)(0.31) = 5.58 × 10^-6

x = √(5.58 × 10^-6) ≈ 2.36 × 10^-3 M

Since x = [H⁺], the pH is:

pH = -log10(2.36 × 10^-3) ≈ 2.63

This is the widely accepted answer for the pH of a 0.31 M acetic acid solution when Ka is 1.8 × 10^-5 at 25°C.

Exact quadratic method

For the exact approach, solve:

x² + Kax – KaC = 0

where C = 0.31 and Ka = 1.8 × 10^-5. The physically meaningful root is:

x = [-Ka + √(Ka² + 4KaC)] / 2

Substituting values gives x very close to 2.35 × 10^-3 M, and therefore:

pH ≈ 2.63

The exact and approximate answers differ only slightly because the percent ionization is low. This confirms that the approximation is justified.

Final answer

The pH of a 0.31 M CH3COOH solution is approximately 2.63 when you use Ka = 1.8 × 10^-5 at 25°C.

Why acetic acid does not behave like a strong acid

A common student mistake is to assume that a 0.31 M acid solution must have [H⁺] = 0.31 M. That would only be valid for a strong monoprotic acid such as HCl, where ionization is essentially complete in dilute aqueous solution. Acetic acid is different because it establishes an equilibrium with water rather than dissociating to completion.

If acetic acid were strong, the pH would be:

pH = -log10(0.31) ≈ 0.51

But the actual pH is near 2.63, which is more than two pH units higher and corresponds to a hydronium concentration that is dramatically lower than 0.31 M. That difference is the direct consequence of weak acid behavior and the relatively small Ka value.

Scenario	[H⁺] Used	Calculated pH	Interpretation
Incorrect strong acid assumption	0.31 M	0.51	Assumes 100% ionization, not valid for CH3COOH
Weak acid approximation	2.36 × 10^-3 M	2.63	Fast and accurate when x is small relative to C
Exact quadratic method	2.35 × 10^-3 M	2.63	Most rigorous equilibrium result

Percent ionization of 0.31 M acetic acid

Another useful metric is percent ionization, which tells you what fraction of the original acetic acid molecules actually release protons. The expression is:

Percent ionization = ([H+]eq / Cinitial) × 100

Using [H⁺] ≈ 2.35 × 10^-3 M and C = 0.31 M:

Percent ionization ≈ (2.35 × 10^-3 / 0.31) × 100 ≈ 0.76%

This is well below 5%, which is the common threshold used to justify the weak acid approximation. In other words, less than 1% of the acetic acid ionizes under these conditions, which explains why the approximation method works so well.

What values should you memorize for acetic acid?

In many general chemistry and analytical chemistry settings, the most frequently used values for acetic acid are:

Formula: CH3COOH
Ka at 25°C: about 1.8 × 10^-5
pKa at 25°C: about 4.76
Conjugate base: acetate, CH3COO^–

These values are central to calculations involving weak acid equilibria, buffers, titrations, and Henderson-Hasselbalch applications.

Acetic Acid Concentration (M)	Approximate [H⁺] (M)	Approximate pH	Percent Ionization
0.010	4.24 × 10^-4	3.37	4.24%
0.050	9.49 × 10^-4	3.02	1.90%
0.100	1.34 × 10^-3	2.87	1.34%
0.310	2.36 × 10^-3	2.63	0.76%
1.000	4.24 × 10^-3	2.37	0.42%

Detailed reasoning behind the approximation

The weak acid approximation comes from observing that Ka is very small. For a weak monoprotic acid, if Ka is much smaller than the initial concentration, the amount dissociated is usually tiny compared with the starting amount. In practical terms, subtracting x from 0.31 changes the denominator by less than 1%, so treating 0.31 – x as simply 0.31 barely affects the answer.

In this problem, x is about 0.00235 M, while the initial concentration is 0.31 M. The ratio x/C is approximately 0.0076, or 0.76%. Since that is well under 5%, the approximation is entirely reasonable.

Common mistakes when solving this problem

Treating CH3COOH as a strong acid. This leads to a pH that is far too low.
Using pKa directly as pH. pKa and pH are not the same thing unless a specific buffer condition exists.
Forgetting the negative sign in pH = -log[H+].
Dropping units or scientific notation errors. A value like 2.35 × 10^-3 must be entered correctly into the logarithm.
Using the wrong Ka value. Small differences in Ka can slightly change the final pH.

How this connects to broader acid-base chemistry

This specific calculation is not just an isolated homework exercise. It illustrates several major concepts in chemistry: equilibrium, conjugate acid-base pairs, logarithmic scales, and approximation methods. Mastering weak acid calculations helps with later topics such as buffer design, biological pH control, solubility equilibria, and titration curve analysis.

For example, acetic acid and acetate together make one of the most familiar buffer systems used in laboratory chemistry. Knowing the pH of pure acetic acid solution is the first step toward understanding how adding sodium acetate shifts the equilibrium and changes the pH according to the Henderson-Hasselbalch equation.

Authoritative educational references

If you want to verify weak acid methods, pH concepts, and acid-base constants, these sources are useful:

Quick summary

To calculate the pH of a 0.31 M CH3COOH solution, write the acetic acid dissociation equilibrium, set up the ICE table, substitute into the Ka expression, solve for the hydronium concentration, and then take the negative base-10 logarithm. Using Ka = 1.8 × 10^-5, the hydronium concentration is about 2.35 × 10^-3 M, giving a final pH of about 2.63.

Important: this result assumes a standard Ka value near 25°C and idealized dilute-solution behavior. If your course uses a slightly different Ka, your final pH may vary by a few hundredths.

Calculate The Ph Of A 0.31 M Ch3Cooh Solution