For a reversible reaction `A underset(K_(2))overset(K_(1))(hArr) `B rate constant `K_(1)` (forward) = `10^(15)e^(-(200)/(T))` and `K_(2)` (backward) = `10^(12)e^(-(200)/(T))`. What is the value of `(-Delta G^(@))/(2.303 RT)` ?

In the reversible reaction 2NO_(2) underset(k_(2))overset(k_(1))(hArr)N_(2)O_(4) the rate of disappearance of NO_(2) is equal to

What is the ratio of the rate constants K_(1) and K_(2) ?

The rate constant K_(1) and K_(2) for two different reactions are are 10^(16)e^(-2000//T) and 10^(15)e^(-1000//T) , respectively. The temperature at which K_(1)=K_(2) is

For the reaction, following data is given: AtoB,K_(1)=10^(15)"exp"^(((-2000)/T)),CtoD,K_(2)=10^(14)"exp"^(((-1000)/T)) The temperature at which K_(1)=K_(2) is

In hypothetical reversible reaction underset((1M))(A)underset(t_(1//2)=2"min")overset(t_(1//2)=6.93"min")(hArr)underset((0.4M))(B) Forward reaction =1st order Backward reaction =0 order What is the rate of disappearance of A at the given moment?

For the reaction, following data is given AtoB:K_(1)=10^(15) exp ((-2000)/T)" "CtoD,K_(2)=10^(14) exp ((-1000)/T) The temperature at whilch K_(1)=K_(2) is

For the reaction CO_((g)) + (1)/(2) O_(2(g)), K_(1)//K_(c) is