Consider the following statements : (i) increase in concentration of reactant increases the rate of a zero order reaction (ii) rate constant k is equal to collision frequency A if `E_a = 0`. (iii) rate constant k is equal to collision frequency A if `E_a = prop`. (iv) In k vs T is a straight line. (v) Ink vs IT is a straight line. Correct statements are

In a first-order reaction A rarr B, if k is rate constant and initial concentration of the reactant A is 0.5 M, then the half-life is :

Identify the reaction order for each of the following rate constants - k=5.0 xx 10^-6 atm^-1 s^-1

According to Arrhenius equation rate constant k is equal to A e^(-Ea//RT) . Which of the following options represents the graph of In k vs 1/T ?

For a certain chemical reaction, Variation in the concentration, In[R] vs time (min) plot is shown below: For this reaction : What are the units of rate constant, k for this reaction ?

If the concentration be expressed in mol L^-1 units and time in seconds, what would be units for rate constant, k for a zero order reaction?

Which of the following is incorrect statement ? a) Stoichiometry of a reaction tells about the order of the elementary reaction. b) For a zero order reaction. Rate and the rate constant are identical . c) A zero order reaction is controlled by factors other than concentration of reactants d) A zero order reaction is an elementary reaction

The initial concentration of N_2O_5 in the following first order reaction N_2O_5(g) rarr 2 NO_2(g) + 1/2O_2 (g) was 1.24 x 10^(-2) mol L^(-1) Calculated the rate constant of the reaction at 318 K.

Rate constant 'k' of a reaction varies with temperature 'T' according to the equation: log k= log A- (E_a)/(2.303R) (1/T) where E_a is the activation energy. When a graph is plotted for log k vs. 1/T , a straight line with a slope of - 4250 K is obtained. Calculate E_a for the reaction (R = 8.314 JK^-1 mol^-1)

Read the given passage and answers following questions : A catalytic process in which the catalyst and the reactants are present in different phases is known as a heterogeneous catalysis. This heterogeneous catalytic action can be explained in terms of the adsorption theory. The mechanism of catalysis involves the following steps: (i) Adsorption of reactant molecules on the catalyst surface. (ii) Occurrence of a chemical reaction through the formation of an intermediate. (iii) De-sorption of products from the catalyst surface (iv) Diffusion of products away from the catalyst surface. In this process, the reactants are usually present in the gaseous state and the catalyst is present in the solid state. Gaseous molecules are then adsorbed on the surface of the catalyst. As the concentration of reactants on the surface of the catalyst increases, the rate of reaction also increases. In such reactions, the products have very less affinity for the catalyst and are quickly desorbed, thereby making the surface free for other reactants. What is diffusion ?