NVAMediumJEE 2026Integrated Rate Laws

JEE Chemistry 2026 Question with Solution

For the thermal decomposition of reactant AB(g), the following plot is constructed.

A graph of concentration [AB]/M versus time in seconds showing a straight decreasing line from about 0.6 at time 0, passing through about 0.55 at 100 s and 0.50 at 200 s.

The half life of the reaction is 'x' min.

x = _____ min. (Nearest integer)

Answer

Correct answer:10

Step-by-step solution

Standard Method

Given: A plot of [AB][AB] versus time is provided, and the line decreases linearly with time.

Find: The half-life xx in minutes.

From the graph, the yy-axis is [AB][AB], not ln[AB]\ln[AB] or 1/[AB]1/[AB]. Therefore, the reaction is zero order.

For a zero-order reaction:

[AB]t=[AB]0kt[AB]_t = [AB]_0 - kt

From the graph:

  • at t=0t = 0, [AB]00.60M[AB]_0 \approx 0.60 \, \text{M}
  • at t=100st = 100 \, \text{s}, [AB]0.55M[AB] \approx 0.55 \, \text{M}
  • at t=200st = 200 \, \text{s}, [AB]0.50M[AB] \approx 0.50 \, \text{M}

So the rate constant is obtained from the slope magnitude:

k=0.600.55100=0.05100=5×104M s1k = \frac{0.60 - 0.55}{100} = \frac{0.05}{100} = 5 \times 10^{-4} \, \text{M s}^{-1}

For a zero-order reaction, half-life is:

t1/2=[AB]02kt_{1/2} = \frac{[AB]_0}{2k}

Substituting the values:

t1/2=0.602×5×104=0.60103=600st_{1/2} = \frac{0.60}{2 \times 5 \times 10^{-4}} = \frac{0.60}{10^{-3}} = 600 \, \text{s}

Convert into minutes:

600s=10min600 \, \text{s} = 10 \, \text{min}

Therefore, the value of xx is 1010.

The solution states an inconsistent second-order interpretation and a final value of 44, but that does not match the provided graph or the listed correct answer. Using the graph, the correct numerical answer is 1010.

Reading the Graph Carefully

Given: The graph is a straight-line plot of [AB][AB] against time.

Find: The half-life.

A straight-line decrease of concentration with time corresponds to a zero-order reaction, because:

[A]=[A]0kt[A] = [A]_0 - kt

Half-life for zero order is not constant in general form and is given by:

t1/2=[A]02kt_{1/2} = \frac{[A]_0}{2k}

Now read the graph directly. The concentration falls from 0.60M0.60 \, \text{M} to 0.50M0.50 \, \text{M} in 200s200 \, \text{s}. Hence,

k=0.600.50200=0.10200=5×104M s1k = \frac{0.60 - 0.50}{200} = \frac{0.10}{200} = 5 \times 10^{-4} \, \text{M s}^{-1}

Initial concentration is:

[AB]0=0.60M[AB]_0 = 0.60 \, \text{M}

So,

t1/2=0.602×5×104=600st_{1/2} = \frac{0.60}{2 \times 5 \times 10^{-4}} = 600 \, \text{s}

Thus,

t1/2=10mint_{1/2} = 10 \, \text{min}

Therefore, the nearest integer value is 1010.

Common mistakes

  • Mistake: Treating the graph as 1/[AB]1/[AB] vs time only because it is a straight line. Why wrong: the axis label clearly shows [AB]/M[AB]/\text{M}. What to do instead: always identify the quantity plotted on the yy-axis before deciding the reaction order.

  • Mistake: Using the first-order half-life formula. Why wrong: first-order reactions require a straight line in ln[A]\ln[A] vs tt, not in [A][A] vs tt. What to do instead: for a linear [A][A] vs tt graph, use the zero-order relation and then apply t1/2=[A]02kt_{1/2} = \frac{[A]_0}{2k}.

  • Mistake: Reading the slope without converting units. Why wrong: the graph time scale is in seconds, but the answer is asked in minutes. What to do instead: calculate t1/2t_{1/2} in seconds first, then divide by 6060 to convert to minutes.

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