(C) Let the rate law be $r = K[A]^x[B]^y$.Using the given data:$0.10 = K[0.012]^x[0.035]^y$ $(1)$$0.80 = K[0.012]^x[0.070]^y$ $(2)$Dividing $(2)$ by

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(C) Let the rate law be $r = K[A]^x[B]^y$.Using the given data:$0.10 = K[0.012]^x[0.035]^y$ $(1)$$0.80 = K[0.012]^x[0.070]^y$ $(2)$Dividing $(2)$ by $(1)$:$8 = (0.070 / 0.035)^y = 2^y$$2^3 = 2^y \implies y = 3$Using experiment $(3)$ and $(1)$:$0.20 = K[0.024]^x[0.035]^y$ $(3)$$0.10 = K[0.012]^x[0.035]^y$ $(1)$Dividing $(3)$ by $(1)$:$2 = (0.024 / 0.012)^x = 2^x$$2^1 = 2^x \implies x = 1$Thus,the rate law is $r = K[A]^1[B]^3$.

Class 12 Chemistry Chemical Kinetics Rate law , Rate constant , Order of Reaction and Molecularity

Medium

For the reaction $A + B \rightarrow C$,select the appropriate rate law based on the following data:
$1$. $[A] = 0.012, [B] = 0.035 \rightarrow \text{Initial Rate} = 0.10$
$2$. $[A] = 0.024, [B] = 0.070 \rightarrow \text{Initial Rate} = 1.6$
$3$. $[A] = 0.024, [B] = 0.035 \rightarrow \text{Initial Rate} = 0.20$
$4$. $[A] = 0.012, [B] = 0.070 \rightarrow \text{Initial Rate} = 0.80$

A
Rate $= K[B]^3$
B
Rate $= K[B]^4$
C
Rate $= K[A]^1[B]^3$
D
Rate $= K[A]^2[B]^2$

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Class 12

Chemistry Questions

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Chemical Kinetics

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Rate law , Rate constant , Order of Reaction and Molecularity

The mechanism of the reaction,$2NO_{(g)} + 2H_{2(g)} \to N_{2(g)} + 2H_2O_{(g)}$ is:
Step $1$: $2NO_{(g)} + H_{2(g)} \xrightarrow{\text{slow}} N_2 + H_2O_2$
Step $2$: $H_2O_2 + H_2 \xrightarrow{\text{fast}} 2H_2O$
Then the correct statement is:

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Give two examples of zero-order reactions and two examples of first-order reactions.

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For the reaction $H_{2(g)} + Br_{2(g)} \to 2HBr_{(g)}$,the experimental data suggest,$\text{rate} = K[H_2][Br_2]^{1/2}$. The molecularity and order of the reaction are respectively:

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What is the time taken for the $3^{rd}$ half-life of a second-order decomposition reaction,given that its first half-life is $20 \ s$ (in $s$)?

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For which type of reactions,order and molecularity have the same value?

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The mechanism of the reaction,$2NO_{(g)} + 2H_{2(g)} \to N_{2(g)} + 2H_2O_{(g)}$ is:Step $1$: $2NO_{(g)} + H_{2(g)} \xrightarrow{\text{slow}} N_2 + H_2O_2$Step $2$: $H_2O_2 + H_2 \xrightarrow{\text{fast}} 2H_2O$Then the correct statement is:

Give two examples of zero-order reactions and two examples of first-order reactions.

For the reaction $H_{2(g)} + Br_{2(g)} \to 2HBr_{(g)}$,the experimental data suggest,$\text{rate} = K[H_2][Br_2]^{1/2}$. The molecularity and order of the reaction are respectively:

What is the time taken for the $3^{rd}$ half-life of a second-order decomposition reaction,given that its first half-life is $20 \ s$ (in $s$)?

For which type of reactions,order and molecularity have the same value?

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The mechanism of the reaction,$2NO_{(g)} + 2H_{2(g)} \to N_{2(g)} + 2H_2O_{(g)}$ is:
Step $1$: $2NO_{(g)} + H_{2(g)} \xrightarrow{\text{slow}} N_2 + H_2O_2$
Step $2$: $H_2O_2 + H_2 \xrightarrow{\text{fast}} 2H_2O$
Then the correct statement is: