NCERT Solutions for Class 12 Chemistry Chapter 4 Chemical Kinetics

NCERT Solutions for Class 12 Chemistry Chapter 4 Chemical Kinetics – Free PDF Download

NCERT Solutions for Class 12 Chemistry Chapter 4 Chemical Kinetics are the study materials that will help students in getting tuned in with the concepts involved in chemical kinetics. The NCERT Solutions for Class 12 Chemistry PDF for chemical kinetics are helpful for the students of CBSE Class 12. These NCERT Solutions are prepared by subject experts at BYJU’S according to the latest CBSE Syllabus for 2023-24 in simple language for easy understanding.

Students aspiring to make a career in the medical or engineering field must practise the NCERT Solutions for Class 12 Chemistry to score well in the board exams as well as various competitive entrance exams. Further, these solutions can also assist students in preparing notes of important concepts or formulae. Students can get the free PDF of the NCERT Solutions for Class 12 Chemistry Chapter 4 by clicking the link provided below.

NCERT Solutions for Class 12 Chemistry Chapter 4 Chemical Kinetics

Download PDF

carouselExampleControls112

Previous

Next

Class 12 Chemistry NCERT Solutions (Chemical Kinetics) – Important Questions

Q 1. From the rate expression for the following reactions, determine their order of reaction and the dimensions of the rate constants.

(a)

\(\begin{array}{l}3\; NO(g) \rightarrow N_{2}O (g) \; Rate = k\left [ NO \right ]^{2}\end{array} \)

(b)

\(\begin{array}{l}H_{2} O_{2} (aq) + 3I^{-}(aq) + 2H^{+} \rightarrow 2H_{2}O (I) + I^{-} \; Rate = k \left [ H^{2}O^{2} \right ]\left [ I^{-} \right ]\end{array} \)

(c)

\(\begin{array}{l}CH_{3}CHO (g) \rightarrow CH_{4} (g) + CO (g) \; Rate = k\left [ CH_{3} CHO \right ]^{\frac{3}{2}}\end{array} \)

(d)

\(\begin{array}{l}C_{2}H_{5}Cl (g) \rightarrow C_{2}H_{4} (g) + HCl (g) \; Rate = k\left [ C_{2} H_{5}Cl \right ]\end{array} \)

Ans:

(a) Given rate =

\(\begin{array}{l}k\left [ NO \right ]^{2}\end{array} \)

Therefore, the order of the reaction = 2

Dimensions of

\(\begin{array}{l}k = \frac{Rate}{\left [ NO \right ]^{2}}\end{array} \)

\(\begin{array}{l}\\ = \frac{mol \; L^{-1} s^{-1}}{\left ( mol \; L^{-1} \right )^{2}} \\ \\ = \frac{mol \; L^{-1} s^{-1}}{mol^{2}\; L^{-2}} \\ \\ = L \; mol^{-1} s^{-1}\end{array} \)

(b) Given rate =

\(\begin{array}{l}k[ H_{2}O_{2} ][ I ^{-}]\end{array} \)

Therefore, the order of the reaction = 2

Dimensions of

\(\begin{array}{l}k = \frac{Rate}{\left [ H_{2}O_{2} \right ]\left [ I^{-} \right ]}\end{array} \)

\(\begin{array}{l}\\ = \frac{mol \; L^{-1} S^{-1}}{\left ( mol \; L^{-1} \right ) \left ( mol \; L^{-1} \right )} \\ \\ = L \; mol^{-1} s^{-1}\end{array} \)

\(\begin{array}{l}= k \left [ CH_{3} CHO \right ]^{\frac{3}{2}}\end{array} \)

Therefore, the order of reaction =

\(\begin{array}{l}\frac{3}{2}\end{array} \)

Dimensions of

\(\begin{array}{l}k = \frac{Rate}{\left [ CH_{3} CHO \right ]^{\frac{3}{2}}} \\ \\ = \frac{mol \; L^{-1}s^{-1}}{\left (mol \; L^{-1} \right )^{\frac{3}{2}}} \\ \\ = \frac {mol\; L^{-1} s^{-1}}{mol^{\frac{3}{2}}\; L^{\frac{3}{2}}} \\ \\ L^{\frac{1}{2}}\; mol^{ -\frac{1}{2}} \; s^{-1}\end{array} \)

(d) Given rate =

\(\begin{array}{l}k = \left [ C_{2}H_{5}Cl \right ]\end{array} \)

Therefore, the order of the reaction = 1

Dimension of

\(\begin{array}{l}k = \frac{Rate}{\left [ C_{2}H_{5}Cl \right ]} \\ \\ = \frac{mol\; L^{-1} s^{-1}}{mol \; L^{-1}} \\ \\ = s^{-1}\end{array} \)

Q 2. For the reaction:

\(\begin{array}{l}2A + B \rightarrow A_{2}B\end{array} \)

is
\(\begin{array}{l}k\left [ A \right ]\left [ B \right ]^{2}\end{array} \)
with
\(\begin{array}{l}k = 2.0 \times 10^{-6}\; mol^{-2}L^{2} \; s^{-1}\end{array} \)
. Calculate the initial rate of the reaction when [A] = 0.1 mol L^–1, [B] = 0.2 mol L^–1. Calculate the rate of reaction after [A] is reduced to 0.06 mol L^–1

Ans:

The initial rate of reaction is

Rate =

\(\begin{array}{l}k\left [ A \right ]\left [ B \right ]^{2} \\ \\ = \left ( 2.0 \times 10^{-6} mol^{-2} L^{2} s^{-1} \right )\left ( 0.1 \; mol \; L^{-1} \right )\left ( 0.2 \; mol \; L^{-1} \right )^{2} \\ \\ = 8.0 \times 10^{-9} mol^{-2}L^{2} s^{-1}\end{array} \)

When [A] is reduced from

\(\begin{array}{l}0.1 \; mol\; L^{-1} \; to \; 0.06 \; mol\; L^{-1}\end{array} \)

, the concentration of A reacted =

\(\begin{array}{l}\left (0.1 – 0.06 \right ) \; mol\; L^{-1} = 0.04 \; mol\; L^{-1}\end{array} \)

Therefore, the concentration of B reacted

\(\begin{array}{l}= \frac {1}{2} \times 0.04 \; mol \; L^{-1} = 0.02 \; mol \; L^{-1}\end{array} \)

Then, the concentration of B available,

\(\begin{array}{l}\left [ B \right ] = \left ( 0.2 – 0.02 \right ) mol \; L^{-1} = 0.18\; mol \; L^{-1}\end{array} \)

After [A] is reduced to

\(\begin{array}{l}0.06 \; mol \; L^{-1}\end{array} \)

, the rate of the reaction is given by,

Rate =

\(\begin{array}{l}k \left [ A \right ]\left [ B \right ]^{2} \\ \\ = \left ( 2.0 \times 10^{-6} mol^{-2}L^{2}s^{-1} \right )\left ( 0.06\; mol L^{-1} \right )\left ( 0.18 \; mol \; L^{-1} \right )^{2} \\ \\ = 3.89\; \times 10^{-9} mol \; L^{-1} s^{-1}\end{array} \)

Q 3. The decomposition of NH₃ on the platinum surface is zero order reaction. What are the rates of production of N₂ and H₂ if k = 2.5 × 10^–4 mol^–1 L s^–1?

Ans:

The decomposition of NH3 on the platinum surface is represented by the following equation:

\(\begin{array}{l}2NH^{3(g)} \overset{Pt}{\rightarrow} N_{2(g)} + 3H_{2(g)}\end{array} \)

Therefore,

\(\begin{array}{l}Rate = -\frac{1}{2}\frac{d\left [ NH_{3} \right ]}{dt} = \frac{d\left [ N_{2} \right ]}{dt} = \frac{1}{3}\frac{d\left [ H_{2} \right ]}{dt}\end{array} \)

However, it is given that the reaction is of zero order.

Therefore,

\(\begin{array}{l}-\frac{1}{2}\frac{d\left [ NH_{3} \right ]}{dt} = \frac{d\left [ N_{2} \right ]}{dt} = \frac{1}{3}\frac{d\left [ H_{2} \right ]}{dt} = k \\ \\ = 2.5 \times 10^{-4}\; mol L^{-1} s^{-1}\end{array} \)

Therefore, the rate of production of

\(\begin{array}{l}N_{2}\end{array} \)

\(\begin{array}{l}\frac{d\left [N_{2} \right ]}{dt} = 2.5 \times 10^{-4} mol\;L^{-1}s^{-1}\end{array} \)

And, the rate of production of

\(\begin{array}{l}H_{2}\end{array} \)

\(\begin{array}{l}\frac{d\left [H_{2} \right ]}{dt} = 3 \times 2.5 \times 10^{-4} mol\;L^{-1}s^{-1} \\ \\ = 7.5 \times 10^{-4} \; mol \;L^{-1}s^{-1}\end{array} \)

Q 4. The decomposition of dimethyl ether leads to the formation of

\(\begin{array}{l}CH_{4}, H_{2}, \; and \; CO\end{array} \)

and the reaction rate is given by
\(\begin{array}{l}Rate = k\left [ CH_{3} O\, C\! H_{3} \right ]^{\frac{3}{2}}\end{array} \)

The rate of reaction is followed by an increase in pressure in a closed vessel, so the rate can also be expressed in terms of the partial pressure of dimethyl ether, i.e.,

\(\begin{array}{l}Rate = k\left ( P_{CH_{3} O\, C\! H_{3}} \right )^{\frac{3}{2}}\end{array} \)

If the pressure is measured in bar and time in minutes, then what are the units of rate and rate constants?

The decomposition of dimethyl ether leads to the formation of CH₄, H₂ and CO and the reaction rate is given by Rate = k [CH₃OCH₃] ^3/2 The rate of reaction is followed by an increase in pressure in a closed vessel, so the rate can also be expressed in terms of the partial pressure of dimethyl ether, Rate = k p_(CHOCH3)^3/2. If the pressure is measured in bar and time in minutes, then what are the units of rate and rate constants?

Ans:

If pressure is measured in bar and time in minutes, then

Unit of rate =

\(\begin{array}{l}bar \; min^{-1}\end{array} \)

\(\begin{array}{l}Rate = k\left ( P_{CH_{3} O\, C\! H_{3}} \right )^{\frac{3}{2}} \\ \\ \Rightarrow k = \frac{Rate}{k\left ( P_{CH_{3} O\, C\! H_{3}} \right )^{\frac{3}{2}}}\end{array} \)

Therefore, the unit of rate constants

\(\begin{array}{l}(k) = \frac{bar\; min^{-1}}{bar^{\frac{3}{2}}} \\ \\ = bar^{\frac{-1}{2}}min^{-1}\end{array} \)

Q 5. Mention the factors that affect the rate of a chemical reaction.

Ans:

The factors which are responsible for the effect on the chemical reaction’s rate are

(a) Reaction temperature

(b) Presence of a catalyst

(d) Nature of the products and reactants

(e) Radiation exposure

(f) Surface area

Q 6. A reaction is second order with respect to a reactant. How is the rate of reaction affected if the concentration of the reactant is (i) doubled (ii) reduced to half?

Ans:

Let the concentration of the reactant be [A] = a

Rate of reaction,

\(\begin{array}{l}R = k [A]^{2}\\ \\ = ka^{2}\end{array} \)

(a) If the concentration of the reactant is doubled, i.e., [A] = 2a, then the rate of the reaction would be

\(\begin{array}{l}R’ = k\left ( A \right )^{2} \\ \\ = 4 ka^{2} \\ \\ = 4 \; R\end{array} \)

Therefore, the rate of the reaction now will be 4 times the original rate.

(b) If the concentration of the reactant is reduced to half, i.e.,

\(\begin{array}{l}\left [ A \right ] = \frac{1}{2}a\end{array} \)

, then the rate of the reaction would be

\(\begin{array}{l}R” = k\left ( \frac{1}{2} a \right )^{2} \\ \\ = \frac{1}{4} k a \\ \\ = \frac{1}{4} R\end{array} \)

Therefore, the rate of the reaction will be reduced to

\(\begin{array}{l}\frac{1}{4} ^{th}\end{array} \)

Q 7. What is the effect of temperature on the rate constant of a reaction? How can this effect of temperature on rate constant be represented quantitatively?

Ans:

When a temperature of

\(\begin{array}{l}10^{ \circ }\end{array} \)

rises for a chemical reaction, then the rate constant increases and becomes near to double its original value.

The temperature effect on the rate constant can be represented quantitatively by the Arrhenius equation.

\(\begin{array}{l}k = Ae^{ -E_{a} / RT}\end{array} \)

Where,

k = rate constant

A = Frequency factor / Arrhenius factor

R = gas constant

T = temperature

\(\begin{array}{l}E_{a}\end{array} \)

= activation energy for the reaction.

Q 8. In a pseudo-first-order reaction in water, the following results were obtained:

t/s	0	30	60	90
[Ester]mol / L	0.55	0.31	0.17	0.085

Calculate the average rate of reaction between the time interval of 30 to 60 seconds.

Ans:

(a) The avg rate of reaction between the time intervals, 30 to 60 seconds,

\(\begin{array}{l}= \frac{d\left [ Ester \right ]}{dt} \\ \\ = \frac{0.31 – 0.17}{60 – 30} \\ \\ = \frac{0.14}{30} \\ \\ = 4.67 \times 10^{-3}\; mol \; l^{-1}\; s^{-1}\end{array} \)

(b) For a pseudo-first-order reaction,

\(\begin{array}{l}\\k = \frac{2.303}{t} \log \frac{\left [ R \right ]_{0}}{\left [ R \right ]}\\ \\ For \; t = 30\; s \\ \\ k_{1} = \frac{2.303}{30} \log \frac{ 0.55}{ 0.31} \\ \\ = 1.911 \times 10^{-2} s^{-1} \\ \\ For \; t = 60\; s \\ \\ k_{2} = \frac{2.303}{60} \log \frac{ 0.55}{ 0.17} \\ \\ = 1.957 \times 10^{-2} s^{-1} \\ \\ For \; t = 90\; s \\ \\ k_{3} = \frac{2.303}{90} \log \frac{ 0.55}{ 0.085} \\ \\ = 2.075 \times 10^{-2} s^{-1}\end{array} \)

Then, the avg rate constant,

\(\begin{array}{l}k = \frac{k_{1} + k_{2} + k_{3}}{3} \\ \\ = \frac{\left (1.911 \times 10^{-2} \right ) + \left (1.957 \times 10^{-2} \right ) + \left (2.075 \times 10^{-2} \right )}{3} \\ \\ = 1.98 \times 10^{-2}\;s^{-1}\end{array} \)

Q 9. A reaction is first order in A and second order in B.
(i) Write the differential rate equation.
(ii) How is the rate affected by increasing the concentration of B three times?
(iii) How is the rate affected when the concentrations of both A and B are doubled?

Ans:

(a) The differential rate equation will be

\(\begin{array}{l}-\frac{d\left [ R \right ]}{dt} = k\left [ A \right ]\left [ B \right ]^{2}\end{array} \)

(b) If the concentration of B is increased three times, then

\(\begin{array}{l}-\frac{d\left [ R \right ]}{dt} = k\left [ A \right ]\left [ 3B \right ]^{2} \\ \\ = 9. k\left [ A \right ]\left [ B \right ]^{2}\end{array} \)

Therefore, the reaction rate will be increased by 9 times.

\(\begin{array}{l}-\frac{d\left [ R \right ]}{dt} = k\left [ 2A \right ]\left [ 2B \right ]^{2} \\ \\ = 8. k\left [ A \right ]\left [ B \right ]^{2}\end{array} \)

Therefore, the rate of reaction will increase 8 times.

Q10. In a reaction between A and B, the initial rate of reaction (r₀) was measured for different initial concentrations of A and B as given below:

\(\begin{array}{l}A/mol\; L^{-1}\end{array} \)	0.20	0.20	0.40
\(\begin{array}{l}B/mol\; L^{-1}\end{array} \)	0.30	0.10	0.05
\(\begin{array}{l}r_{0}/mol\; L^{-1}\; s^{-1}\end{array} \)	\(\begin{array}{l}5.07 \times 10^{-5}\end{array} \)	\(\begin{array}{l}5.07 \times 10^{-5}\end{array} \)	\(\begin{array}{l}1.43 \times 10^{-4}\end{array} \)

What is the order of the reaction with respect to A and B?

Ans:

Let the order of the reaction with respect to A be x and with respect to B be y.

Then,

\(\begin{array}{l}r_{0} = k\left [ A \right ]^{x} \left [ B \right ]^{y} \\ \\ 5.07 \times 10^{-5} = k\left [ 0.20 \right ]^{x}\left [ 0.30 \right ]^{y} \;\;\;\; (i) \\ \\ 5.07 \times 10^{-5} = k\left [ 0.20 \right ]^{x}\left [ 0.10 \right ]^{y} \;\;\;\; (ii) \\ \\ 1.43 \times 10^{-4} = k\left [ 0.40 \right ]^{x}\left [ 0.05 \right ]^{y} \;\;\;\; (iii)\end{array} \)

Dividing equation (i) by (ii), we get

\(\begin{array}{l}\frac{5.07 \times 10^{-5} }{5.07 \times 10^{-5} } = \frac{k\left [ 0.20 \right ]^{x}\left [ 0.30 \right ]^{y} }{k\left [ 0.20 \right ]^{x}\left [ 0.10 \right ]^{y} } \\ \\ \Rightarrow 1 = \frac{\left [ 0.30 \right ]^{y}}{\left [ 0.10 \right ]^{y}} \\ \\ \Rightarrow \left ( \frac{0.30}{0.10} \right )^{0} = \left ( \frac{0.30}{0.10} \right )^{y} \\ \\ \Rightarrow y = 0\end{array} \)

Dividing equation (iii) by (ii), we get

\(\begin{array}{l}\frac{1.43 \times 10^{-4}}{5.07 \times 10^{-5}} = \frac{k\left [ 0.40 \right ]^{x}\left [ 0.05 \right ]^{y}}{k\left [ 0.20 \right ]^{x}\left [ 0.30 \right ]^{y}} \\ \\ \Rightarrow \frac{1.43 \times 10^{-4}}{5.07 \times 10^{-5}} = \frac{\left [ 0.40 \right ]^{x}}{\left [ 0.20 \right ]^{x}} \;\;\;\;\; \begin{bmatrix} Since\; y = 0,\\ \left [ 0.05 \right ]^{y} = \left [ 0.30 \right ]^{y} = 1 \end{bmatrix} \\ \\ \Rightarrow 2.821 = 2^{x} \\ \\ \Rightarrow \log 2.821 = x \log 2 \;\;\;\;\; (taking\; log \; on \; both\; sides) \\ \\ \Rightarrow x = \frac{\log 2.821}{\log 2} \\ \\ = 1.496 \\ \\ = 1.5 \; (Approximately)\end{array} \)

Hence, the order of the reaction with respect to A is 1.5 and with respect to B is zero.

Q 11. The following results have been obtained during the kinetic studies of the reaction:
2A + B → C + D

Exp.	\(\begin{array}{l}\frac{A}{mol L^{-1}}\end{array} \)	\(\begin{array}{l}\frac{B}{mol L^{-1}}\end{array} \)	Initial rate of formation of \(\begin{array}{l}\frac{D}{mol\; L^{-1} \;min^{-1}}\end{array} \)
1	0.1	0.1	\(\begin{array}{l}6.0 \times 10^{-3}\end{array} \)
2	0.3	0.2	\(\begin{array}{l}7.2 \times 10^{-2}\end{array} \)
3	0.3	0.4	\(\begin{array}{l}2.88 \times 10^{-1}\end{array} \)
4	0.4	0.1	\(\begin{array}{l}2.4 \times 10^{-2}\end{array} \)

Determine the rate law and the rate constant for the reaction.

Ans:

Let the order of the reaction with respect to A be x and with respect to B be y.

Therefore, the rate of the reaction is given by,

Rate =

\(\begin{array}{l}k\left [ A \right ]^{x} \left [ B \right ]^{y}\end{array} \)

According to the question,

\(\begin{array}{l}6.0 \times 10^{-3} = k\left [ 0.1 \right ]^{x} \left [ 0.1 \right ]^{y}\end{array} \)

——- (1)

\(\begin{array}{l}7.2 \times 10^{-2} = k\left [ 0.3 \right ]^{x} \left [ 0.2 \right ]^{y}\end{array} \)

——–(2)

\(\begin{array}{l}2.88 \times 10^{-1} = k\left [ 0.3 \right ]^{x} \left [ 0.4 \right ]^{y}\end{array} \)

——–(3)

\(\begin{array}{l}2.4 \times 10^{-2} = k\left [ 0.4 \right ]^{x} \left [ 0.1 \right ]^{y}\end{array} \)

——–(4)

Dividing equation (4) by (1), we get

\(\begin{array}{l}\frac{2.4 \times 10^{-2}}{6.0 \times 10^{-3}} = \frac{k\left [ 0.4 \right ]^{x} \left [ 0.1 \right ]^{y}}{k\left [ 0.1 \right ]^{x} \left [ 0.1 \right ]^{y}}\end{array} \)

\(\begin{array}{l}4 = \frac{\left [ 0.4 \right ]^{x}}{\left [ 0.1 \right ]^{x}}\end{array} \)

\(\begin{array}{l}4 = \left (\frac{0.4}{0.1 } \right )^{x}\end{array} \)

\(\begin{array}{l}\left (4 \right )^{1} = \left (4 \right )^{x}\end{array} \)

x = 1

Dividing equation (3) by (2), we get

\(\begin{array}{l}\frac{2.88 \times 10^{-1}}{7.2 \times 10^{-2}} = \frac{k\left [ 0.3 \right ]^{x} \left [ 0.4 \right ]^{y}}{k\left [ 0.3 \right ]^{x} \left [ 0.2 \right ]^{y}}\end{array} \)

\(\begin{array}{l}4 = \left (\frac{0.4}{0.2} \right )^{y}\end{array} \)

\(\begin{array}{l}4 = 2^{y}\end{array} \)

\(\begin{array}{l}2^{2} = 2^{y}\end{array} \)

y = 2

Hence, the rate law is

Rate =

\(\begin{array}{l}k \left [ A \right ] \left [ B \right ]^{2}\end{array} \)

\(\begin{array}{l}k = \frac{Rate}{\left [ A \right ] \left [ B \right ]^{2}}\end{array} \)

From experiment 1, we get

\(\begin{array}{l}k = \frac{6.0 \times 10^{-3} mol\; L^{-1} \;min^{-1}}{\left (0.1 \;mol \;L^{-1} \right ) \left (0.1 \;mol \;L^{-1} \right )^{2}}\end{array} \)

= 6.0