Chemical Kinetics MCQ Questions & Answers in Physical Chemistry | Chemistry
Learn Chemical Kinetics MCQ questions & answers in Physical Chemistry are available for students perparing for IIT-JEE, NEET, Engineering and Medical Enternace exam.
41.
Which of the following is an example of a fractional order reaction?
42.
In the reaction, $$BrO_3^ - \left( {aq} \right) + 5B{r^ - }\left( {aq} \right) + 6{H^ + }$$ $$ \to 3B{r_2}\left( l \right) + 3{H_2}O\left( l \right)$$ the rate of appearance of bromine $$\left( {B{r_2}} \right)$$ is related to rate of disappearance of bromide ions as following.
43.
The rate constant for a first order reaction at $${300^ \circ }C$$ for which $${E_a}$$ is $$35\,kcal\,mo{l^{ - 1}}$$ and frequency constant is $$1.45 \times {10^{11}}{s^{ - 1}}$$ is
44.
Consider the reaction $${N_2}\left( g \right) + 3{H_2}\left( g \right) \to 2N{H_3}\left( g \right)$$ The equality relationship between $$\frac{{d\left[ {N{H_3}} \right]}}{{dt}}$$ and $$ - \frac{{d\left[ {{H_2}} \right]}}{{dt}}$$ is
If we write rate of reaction in terms of concentration of $${N{H_3}}$$ and $${H_2},$$ then
Rate of reaction $$ = \frac{1}{2}\frac{{d\left[ {N{H_3}} \right]}}{{dt}} = - \frac{1}{3}\frac{{d\left[ {{H_2}} \right]}}{{dt}}$$
So, $$\frac{{d\left[ {N{H_3}} \right]}}{{dt}} = - \frac{2}{3}\frac{{d\left[ {{H_2}} \right]}}{{dt}}$$
45.
The rate law for a reaction between the substances $$A$$ and $$B$$ is given by rate $$ = k{\left[ A \right]^n}{\left[ B \right]^m}.$$ On doubling the concentration of $$A$$ and halving
the concentration of $$B,$$ the ratio of the new rate to the earlier rate of the reaction will be as
46.
$${t_{\frac{1}{4}}}$$ can be taken as the time taken for the concentration of a reactant to drop to $$\frac{3}{4}$$ of its initial value. If the rate constant for a first order reaction is $$k,$$ the $${t_{\frac{1}{4}}}$$ can be written as
Such reaction in which two lighter nucleus are fused together to form a heavier nuclei is called nuclear fusion.
NOTE : In hydrogen bomb, a mixture of deuterium oxide $$\left( {{H_2}O} \right)$$ and tritium Oxide $$\left( {{T_2}O} \right)$$ is enclosed in a space surrounding an ordinary atomic bomb. The temperature produced by the atomic bomb initiates the fusion reaction between $$_1{H^3}$$ and $$_1{H^2}$$ releasing a large amount of energy.
48.
In a reaction, $$A + B \to $$ Product, rate is doubled when the concentration of $$B$$ is doubled and rate increases by a factor of 8 when the concentrations of both the reactants ( $$A$$ and $$B$$ ) are doubled. Rate law for the reaction can be written as
A
$${\text{rate}} = k\left[ A \right]{\left[ B \right]^2}$$
B
$${\text{rate}} = k{\left[ A \right]^2}{\left[ B \right]^2}$$
C
$${\text{rate}} = k\left[ A \right]\left[ B \right]$$
D
$${\text{rate}} = k{\left[ A \right]^2}\left[ B \right]$$
Answer :
$${\text{rate}} = k{\left[ A \right]^2}\left[ B \right]$$
Let the order of reaction with respect to $$A$$ and $$B$$ is $$x$$ and $$y$$ respectively. So, the rate law can be given as
$$R = k{\left[ A \right]^x}{\left[ B \right]^y}\,...\left( {\text{i}} \right)$$
When the concentration of only $$B$$ is doubled, the rate is doubled, so
$${R_1} = k{\left[ A \right]^x}{\left[ {2B} \right]^y} = 2R\,...\left( {{\text{ii}}} \right)$$
If concentrations of both the reactants $$A$$ and $$B$$ are doubled, the rate increases by a factor of 8, so
$$\eqalign{
& R'' = k{\left[ {2A} \right]^x}{\left[ {2B} \right]^y} = 8R\,\,\,...\left( {{\text{iii}}} \right) \cr
& \Rightarrow k{2^x}{2^y}{\left[ A \right]^x}{\left[ B \right]^y} = 8R\,\,\,...\left( {{\text{iv}}} \right) \cr
& {\text{From Eqs}}{\text{. (i) and (ii), we get}} \cr
& \Rightarrow \frac{{2R}}{R} = \frac{{{{\left[ A \right]}^x}{{\left[ {2B} \right]}^y}}}{{{{\left[ A \right]}^x}{{\left[ B \right]}^y}}} \cr
& 2 = {2^y} \cr
& \therefore \,\,y = 1 \cr
& {\text{From Eqs}}{\text{. (i) and (iv), we get}} \cr
& \Rightarrow \,\frac{{8R}}{R} = \frac{{{2^x}{2^y}{{\left[ A \right]}^x}{{\left[ B \right]}^y}}}{{{{\left[ A \right]}^x}{{\left[ B \right]}^y}}}\,\,{\text{or}}\,\,8 = {2^x}{2^y} \cr
& {\text{Substitution of the value of }}y{\text{ gives,}} \cr
& {\text{8 = }}{{\text{2}}^x}{2^1} \cr
& 4 = {2^x} \cr
& {\left( 2 \right)^2} = {\left( 2 \right)^x} \cr
& \therefore x = 2 \cr} $$
Substitution of the value of $$x$$ and $$y$$ in Eq. (i) gives,
$$R = k{\left[ A \right]^2}\left[ B \right]$$
49.
$$A \to B,\Delta H = - 10kJ\,mo{l^{ - 1}},{E_{a\left( f \right)}} = 50\,kJ\,mo{l^{ - 1}},$$ then $${E_a}$$ of $$B \to A$$ will be
A
$$40\,kJ\,mo{l^{ - 1}}$$
B
$$50\,kJ\,mo{l^{ - 1}}$$
C
$$ - 50\,kJ\,mo{l^{ - 1}}$$
D
$$60\,kJ\,mo{l^{ - 1}}$$
Answer :
$$60\,kJ\,mo{l^{ - 1}}$$
$$\eqalign{
& A \to B,\Delta H = - 10\,kJ\,mo{l^{ - 1}} \cr
& {\text{It is an exothermic reaction}}{\text{.}} \cr
& {E_{a\left( b \right)}} = {E_{a\left( f \right)}} - \left( {\Delta H} \right) \cr
& = 50 - \left( { - 10} \right) \cr
& = 60\,kJ \cr} $$
50.
For the first order reaction $$A \to B + C$$ is carried out at $${27^ \circ }C.$$ If $$3.8 \times {10^{ - 16}}\% $$ of the reactant molecules exists in the activated state, the $${E_a}$$ (activation energy) of the reaction is :