An equilibrium reaction is endothermic if `K_(1)` and `K_(2)` are the equilibrium constants at `T_(1)` and `T_(2)` temperatures respectively and if `T_(2)` is greater than `T_(1)` then

For a given exothermic reaction, K_P and K_p^' are the equilibrium constants at temperature T_1 and T_2( T_2>T_1) respectively. Assuming the heat of reaction is constant in temperature range between T_1 and T_2 , it is readily observed that

At a given temperature, the reaction, A(g)hArr 2N(g) , is in equilibrium in a closed flask. At the same temperature, the reaction c(g)hArr D(g)+E(g) is in equilibrium in an another closed flask. Values of equilibrium constants of these two reactions are K_(p1) and K_(p2) respectively and the total pressures of the equilibrium mixtures are P_1 and P_2 respectively. If K_(p1) : K_(p2) = 1 : 4 and P_1 : P_2 = 1 : 4 then the ratio of degree of dissociation of A(g) and C(g) are ( assume the degrees of dissociation of both are very small compared to 1)-

Write down the Arrhenius equation relating the rate constant of a reaction with temp. If K_1 and K_2 be the rate constants of reaction at temperature t_1^@C and t_2^@C respectively, Find out the relation between K_1 , K_2 , t_1 and t_2 . Give that the activation energy (E_a) of the reaction remains unchnaged within the temp. range mentioned. The rate constants of a reaction at 400K and 500K are 0.02 S^-1 and 0.085 S^-1 respectively. Determine the activation energy (E_a) of the reaction.

Let f and g be periodic functions with the periods T_(1) and T_(2) respectively. Then f+g is

Write down the Arrhenius equation relating the rate constant of reaction with temperature , mentioning what the terms indicate. If k_(1) and k_(2) be the rate constant of a reaction at temperature t_(1)^(@)C and t_(2)^(@)C , respectively, find out the relation between k_(1) ,k_(2) and t_(1) and t_(2) . Given that the activation energy (E_(a)) of the reaction remains unchanged within the temperature range mentioned. The rate constant of a reaction at 400K and 500K are 0.02s^(-1) and 0.08s^(-1) respectively . Determine the activation energy (E_(a)) of the reaction.

A first order reaction takes t_(1) and t_(2)s for its 20% and 60% completions , respectively . If its half-life is t_(3)s , then -

For endothermic equilibrium, increase in temperature changes the K_(eq) value as

Activation energy (E_(a)) and rate constant (k_(1) and k_(2)) of a chemical reaction at two different temperatures (T_(1) and T_(2)) are related by -

If the equilibrium constants of following reactions are 2A hArr B is K_(1) and B hArr2A is K_(2) , then