Consider an elementary reaction:
\[
A(g) + B(g) \rightarrow C(g) + D(g)
\]
If the volume of the reaction mixture is suddenly reduced to \( \frac{1}{3} \) of its initial volume, the reaction rate will become \( x \) times of the original reaction rate. The value of \( x \) is:
Show Hint
- \( \frac{1}{9} \)
- 9
- 3
- \( \frac{1}{3} \)
The Correct Option is B
Approach Solution - 1
For an elementary reaction, the rate of reaction is proportional to the concentrations of the reactants. Specifically, for a reaction where the stoichiometric coefficients are 1 for both A and B, the rate law can be expressed as: \[ \text{Rate} = k[A][B] \] Here, \( k \) is the rate constant, and \( [A] \) and \( [B] \) are the concentrations of reactants A and B. Now, when the volume of the reaction mixture is reduced to \( \frac{1}{3} \) of its original volume, the concentration of the reactants will increase by a factor of 3, as concentration is inversely proportional to volume. Since the rate is directly proportional to the product of the concentrations of A and B, the reaction rate will increase by: \[ \text{New rate} = k(3[A])(3[B]) = 9 \times (\text{Original rate}) \] Therefore, the reaction rate will become 9 times the original rate. The value of \( x \) is 9.
Approach Solution -2
The elementary reaction is:
\[ A(g) + B(g) \rightarrow C(g) + D(g) \]
Since the reaction is elementary, the rate law is directly determined from the stoichiometric coefficients:
\[ \text{Rate} = k[A][B]. \]
Step 2: Effect of volume reduction.
When the volume of the reaction mixture is reduced to \( \frac{1}{3} \) of its initial volume, the concentrations of all gaseous species will increase because concentration is inversely proportional to volume:
\[ \text{New concentration} = 3 \times \text{Initial concentration}. \]
Step 3: Calculate new rate.
Let the initial concentrations of \( A \) and \( B \) be \([A]\) and \([B]\).
Initial rate: \[ R_1 = k[A][B]. \] After reduction of volume to one-third, new concentrations are \( 3[A] \) and \( 3[B] \).
New rate: \[ R_2 = k(3[A])(3[B]) = 9k[A][B]. \]
Step 4: Ratio of new rate to old rate.
\[ \frac{R_2}{R_1} = \frac{9k[A][B]}{k[A][B]} = 9. \] Hence, the new rate becomes 9 times the original rate.
Final Answer:
\[ \boxed{x = 9} \]
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