Q.102 The pKa of a buffer solution with pH of 5, consisting of 0.4 M sodium acetate and
0.04 M acetic acid, is ______. (Answer in integer)
The pKa of the given buffer solution is 4.
Problem Solution
The buffer consists of acetic acid (weak acid, HA) at 0.04 M and sodium acetate (conjugate base, A⁻) at 0.4 M, with pH 5. Apply the Henderson-Hasselbalch equation:
pH = pKa + log10([A–]/[HA])
Substitute values: 5 = pKa + log10(0.4/0.04). The ratio 0.4/0.04 = 10, so log10(10) = 1. Thus, 5 = pKa + 1, giving pKa = 4.
This assumes initial concentrations approximate equilibrium values, valid for typical buffer problems in exams like CSIR NET.
Article Introduction
The pKa of buffer solution pH 5 with 0.4 M sodium acetate and 0.04 M acetic acid is a key CSIR NET Life Sciences question testing buffer chemistry fundamentals. This acetate buffer example demonstrates precise pKa calculation using the Henderson-Hasselbalch equation, essential for biochemistry and enzyme kinetics topics.
Henderson-Hasselbalch Equation
Buffers resist pH changes via weak acid (HA) and conjugate base (A⁻) equilibrium. The equation is pH = pKa + log10([A–]/[HA]), derived from Ka = [H+][A–]/[HA].
Here, [A⁻] = 0.4 M (sodium acetate), [HA] = 0.04 M (acetic acid), pH = 5. Ratio = 10, log = 1, so pKa = 5 – 1 = 4 (integer).
Step-by-Step Calculation
- Compute ratio: 0.4/0.04 = 10
- Logarithm: log10(10) = 1
- Rearrange: pKa = pH – log(ratio) = 5 – 1 = 4
No options provided; direct integer answer is 4, matching acetic acid’s typical pKa range (4.74-4.76) adjusted for this ratio.
Exam Relevance
For CSIR NET, recognize buffers maintain pH near pKa ±1 for max capacity. This pH 5 setup (pKa 4) falls within effective range. Practice similar problems for molecular biology, biotech sections.
