The equilibrium constants for the reaction `Br_(2)hArr 2Br` at 500 K and 700 K are `1xx110^(-10) and 1xx10^(-5)` respectively.
The reaction is

The equilibrium constants for the reaction Br_(2)hArr 2Br at 500 K and 700 K are 1xx10^(-10) and 1xx10^(-5) respectively. The reaction is:

The equilibrium constants for the reaction Br_(2)hArr 2Br at 500 K and 700 K are 1xx10^(-10) and 1xx10^(-5) respectively. The reaction is:

The equilibrium constants for the reaction, A_2hArr2A A at 500K and 700K are 1xx10^(-10) and 1xx10^(-5) . The given reaction is

The equilibrium constants for A_2 (g) hArr 2A(g) at 400 k and 600 k are 1xx 10^(-8) and 1 xx 10^(-2) respectively . The reaction is

The equilibrium constant for the reaction A(g)hArrB(g) and B(g)hArrC(g) are K_1=10^(-2) and K_2=10^(-1) respectively . Equilibrium constant for the reaction (1/2)C(g)hArr(1/2)A(g) is

For the formation of ammonia the equilibrium constant data at 673K and 773 K , respectively, are 1.64xx10^(-4) and 1.44xx10^(-5) respectively. Calculate heat of reaction (R=8.314 J K^(-1) mol^(-1))

The rate constants of a reaction at 500 K and 700 K are 0.02 s^(-1) and 0.07 s^(-1) respectively. Calculate the values of E_a and A.

The equilibrium constant of a reaction at 298 K is 5 xx 10^(-3) and at 1000 K is 2 xx 10^(-5) What is the sign of triangleH for the reaction.