For the equilibrium , `2NOCl(g)hArr2NO(g)+Cl_(2)(g)` the value of the equilibrium constant, `K_(c)` is `3.75xx10^(-6)` at `1069K`. Calculate the `K_(p)` for the reaction at this temperature ?

In the equilibrium reaction, A(g) + 2B(g) + (g), the equilibrium constant, K_(c) is given by the expression

For the equilibrium SO_(2)Cl_(2(g)) hArr SO_(2(g)) + Cl_(2(g)) . What is the temperature at which (K_(p)(atm))/(K_(c)(M)) = 3 ?

For a reaction 2A_((g)) hArr 2B_((g))+ C_((g)), K_e=3.75xx10^(-1) at 1069 K. The approximate value of K_(p) for this reaction at the same temperature is (R=0.082 L "bar mol"^(-1) K^(-1))

At 100 K the partial pressure of CO_(2) (g ) and CO (g) for the reaction CO_(2)(g) + C(s) hArr 2CO (g ) in a closed vessel at equilibrium are 0.15 and 0.60 bar respectively . The K_(c ) for this reaction at the same temperature is approximately

For the reaction equilibrium 2NOBr_((g)) hArr 2NO2_((g)) + Bz_(2(g)) . If PBr_(2) = (p)/(9) at equilibrium and P is total pressure, the ratio (K_(p))/(p) is equal to

At 125^@C the K_p for the reaction N_2(g)+3H_2(g) leftrightarrow 2NH_3(g) is 2.15 times 10^-6 atm^-2 . Calculate K_c for the equilibrium at same temperature.

K_p for the reaction 2SO_3(g) +O_2(g) leftrightarrow 2SO_3(g) is 2.5 times 10^20 atm^-1 at 500K. Calculate the K_p for the reaction SO_3(g) leftrightarrow SO_2(g)+1/2 O_2(g) .