For a reaction, `E_(a)=0 and k=4.2xx10^(5)sec^(-1)" at "300K`, the value of k at 310 K will be

The activation energy of a reaction is zero . If the rate constant of the reaction at 300K is 3.2xx10^(6)s^(-1) , then at 316K the rate constant of the reaction will be -

The specific reaction rates of a chemical reaction are 2.45xx10^(-5)sec^(-1)" at "273K and 16.2 xx10^(-4) sec^(-1) at 303 K. Calculate the activation energy.

For the reaction X_(2)Y_(4)(l) to 2XY(g) at 300K the values of DeltaU and DeltaS are 2kcal and 20cal*K^(-1) respectively. The value of DeltaG for the reaction is-

For the reaction X_2Y_4(l) to 2 XY_2(g) at 300 K the values of DeltaU and DeltaS are 2 kCal and 20 Cal K^-1 respectively. The value of DeltaG for the reaction is

Velocity Constant for a reaction at 290.K is given by 3.2 xx10^-3 S^-1 . What w ill be its value at 300 K—

For the reaction, SO_2(g) + 1/2 O_2(g) iff SO_3(g) , the value of K_c is 1.7 xx 10^(12) at 300K. Calculate the equilibrium constants for the following reactions at 300K : 2SO_2(g) + O_2(g) iff 2SO_3(g) and SO_3(g) iff SO_2(g) + 1/2O_2(g)

The slope and intercept of a logk vs 1/T graph of a first order reaction is -1.25xx10^(4)k and 14.34 respectively . If at a fixed temperature , the value of k is 4.51xx10^(-5)s^(-1) , then the value of the temperature is -

Specific reaction rates for a reaction at 300K and 310K are 3xx10^(-6) S^(-1) and 2.8xx10^(-5 S^(-1 . Calculate the activation enrgy for that reaction.

Two reactions , R_(1) and R_(2) have identical pre-exponential factors . Activation energy of R_(1) exceeds that of R_(2) by 10"kJ.mol"^(-1) . If k_(1) and k_(2) are rate constants for reaction R_(1) and R_(2) respectively at 300K, then In (K_(2)//k_(1)) is equal to (R=8.314"J.mol"^(-1).k^(-1)) -

Write the relation betweenn DeltaG^(0) and the equilibrium constant (K) for a reaction at TK. Using this relation state that for what value of DeltaG^(0) , the value of K will be K gt 1, K lt 1 , K=1 .