The rate constant for a first-order reaction is $4.606\times {10}^{-3}$ $s^{-1}$. The time required to reduce 2.0 g of the reactant to 0.2 g will be:

1.	200 s	2.	500 s
3.	1000 s	4.	100 s

The decomposition of hydrocarbons follows the equation: k = (4.5 × 10¹¹s^–1) e^–28000K/T

The activation energy (E_a) for the reaction would be:
1. 232.79 kJ mol^–1
2. 245.86 kJ mol^–1
3. 126.12 kJ mol^–1
4. 242.51 kJ mol^–1

An increase in the concentration of the reactants of a reaction leads to a change in:

The correct statement based on the graph below is:
  

At high pressure the following reaction is zero order-

The correct statements among the following is:

Match the graph given in Column I with the order of reaction given in Column II.
More than one item in Column I may be linked to the same item in Column II:

Column I		Column II
(i)		(a)	1st order
(ii)		(b)	Zero order
(iii)
(iv)

The half-life for a zero-order reaction having 0.02 M initial concentration of reactant is 100 s. The rate constant (in mol L^–1 s^–1) for the reaction is:

1. $1.0\times {10}^{-4}$

2. $2.0\times {10}^{-4}$

3. $2.0\times {10}^{-3}$

4. $1.0\times {10}^{-2}$

What does Z_AB represent in the collision theory of chemical reactions?

Select the correct option based on statements below:

For an l^st order reaction, k = (8.5×10⁵)e^–15000K/T. The activation energy of the reaction is:  

1. 150 kJ/mol

2.  125 kJ/mol

3.  50 kJ/mol

4.  500 kJ/mol