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.

0.482 mol N_2 and 0.933 mol O_2 are placed in a 10 L vessel and allowed to form N_2O at constant temperature. Numerical value of K_c for the reaction 2N_2(g)+O_2(g) leftrightarrow 2N_2O(g) is 2 times 10^-37 K mol^-1 . Calculate the equilibrium concentration of nirous oxide.

K_p for the reaction NH_4HS (s) leftrightarrow NH_3(g) +H_2S (g) at certain temperature is 9 bar^2 Calculate the equilibrium pressure.

K_(c) for the reaction N_(2)(g)+3H_(2)(g)hArr2N_(3)(g) is 0.5 at 400K find K_(p)

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) .

K_p for the reaction N_2O_4(g) leftrightarrow 2NO_2(g) at 750K is 640torr. Calculate the percentage of dissociation of N_2O_4 at equilibrium pressure of 160torr.

K_(p) for the reaction N_(2)(g)+3H_(2)(g)hArr2NH_(3)(g) at 400^(2)C is 1.64xx10^(-4) a. Calculate K_(c) d b. Calculate DeltaG^(@) value of K_(c) value.

The reaction was started with 0.1M each of CO and H_2O at 800K. K_c for the chemical reaction , CO(g)+H_2O(g) leftrightarrow CO_2(g)+H_2(g) at 800K is 4.24.Calculate the equilibrium concentration of the lightest gas.

K_c is 6.3 times 10^14 for the reaction NO+O_3 leftrightarrow NO_2+O_2 at 1000K, calculate K_c for the reverse reaction.