The value of `DeltaG^(@)` for a reaction in aqueous phase having `K_(c)=1,` would be :

The rate of a chemical reaction becomes double for every 10^@C rise in temperature. If this generalisation holds for a reaction in the temperature range 290 K to 300 K, what would be the approximate value of E_a for the reaction ?

In general it is observed that the rate of a chemical reaction becomes double for every 10^@ rise in temperature. If this generalisation holds for a reaction in the temperature range 2908 K to 398 K, what would be the value of activation energy for the reaction. (R=8.314 J K^(-1)mol^(-1) )

The value of k for a reaction is 2.96xx10^(30)s^-1 , what is the order of the reaction?

The value of k for a reaction is 2.96 xx 10^(-30)s^(-1) . What is the order of reaction ?

Find the value of p/k for each of the following quadratic equations, so that they have two equal roots— :- k+1)x^2-2(k-1)x+1=0 .

The equilibrium constant for the reaction N_(2)(g)+O_(2)(g) hArr 2NO(g) at temperature T is 4xx10^(-4) .The value of K_(c) for the reaction NO(g) hArr 1/2 N_(2)(g)+1/2 O_(2)(g) at the same temperature is

Calculate DeltaG^(@) (kJ/mol) at 127^(@)C for a reaction with K_("equilibrium")=10^(5) :

The rate law for a reaction of A, B and C has been found to be rate = k [A][B][C]^2 . How would the rate of reaction change when concentration of each of A, B and C are tripled ?