Half-life of zero-order reaction $ A \to $ product is 1 hour, when initial concentration of reaction is 2.0 mol L$^{-1}$. The time required to decrease concentration of A from 0.50 to 0.25 mol L$^{-1}$ is:
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- 0.5 hour
- 4 hour
- 15 min
- 60 min
The Correct Option is C
Approach Solution - 1
To solve the problem, let's consider the details of the reaction given:
The reaction is zero-order, denoted as \( A \to \text{product} \), where the rate is independent of the concentration of the reactant.
The formula for the half-life of a zero-order reaction is:
\(t_{1/2} = \frac{[A]_0}{2k}\)
where \([A]_0\) is the initial concentration and \(k\) is the rate constant.
Given that the half-life (\( t_{1/2} \)) is 1 hour and \([A]_0 = 2.0 \, \text{mol L}^{-1}\), we can calculate \(k\):
\(1 = \frac{2.0}{2k}\)
Solving for \( k \):
\(k = 1.0 \, \text{mol L}^{-1} \text{h}^{-1}\)
Next, we want to find the time required to decrease the concentration of \(A\) from 0.50 mol L-1 to 0.25 mol L-1. For a zero-order reaction, the time (\( t \)) for the concentration change from \([A]_0\) to \([A]\) is given by:
\(t = \frac{[A]_0 - [A]}{k}\)
Substituting the given values:
\(t = \frac{0.50 - 0.25}{1.0} = 0.25 \, \text{hours}\)
Since we need to find the time in minutes:
\(0.25 \, \text{hours} \times 60 \, \text{min/hour} = 15 \, \text{minutes}\)
Therefore, the time required to decrease the concentration of A from 0.50 mol L-1 to 0.25 mol L-1 is 15 minutes.
Hence, the correct answer is: 15 min.
Approach Solution -2
Thus, the time required to decrease the concentration of A from 0.50 to 0.25 mol L\(^{-1}\) is 15 minutes.
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