Peqfor `NH_(4)COONH_(2(s)) harr 2NH_(3(g))+ CO_(2(g))` at certain temperature is 0.9 atm. Then, partial pressure of Ammonia at equilibrium (in atm)

Unit of K_p for NH_4COONH_(2(s)) harr 2NH_(3(g))+ CO_(2(g)) is

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.

For the following reaction NH_(4)HS_((s)) harr NH_(3(g))+H_(2)S_((g)) the total pressure at equilibrium is 30 atm. The value of K_(P) is

Kp value for 2SO_(2(g)) O_(2(g)) hArr 2SO_(3(g)) is 5.0 atm^(-1) . What is the cquilibrium partial pressure of O_(2) if the equilibrium pressures of SO_(2) and SO_(3) are equal ?

In the reaction 2 SO_(3 (g)) , hArr 2 SO_(2 (g)) + O_(2 (g)) , SO_(3 (g)) is 50 % dissociated at 27^(@)C when the equilibrium pressure is 0.5 atm . Partial pressure of SO_(3 (g)) at Equilibrium is

For MgO_((g)) + C_((g)) hArr Mg_((g)) + CO_((g)) , equilibrium pressure at 2000 K is 100 atm . Now K_(p) for the process is (in atm^(2))

Assume that the decomposition of HNO_(3) can be represented by the following equation 4HNO_(3(g)) hArr 4NO_(2(g)) + 2H_(2) O_((g)) + O_(2(g)) and the reaction approaches equilibrium at 400K temperature and the copper turnning 0 atm pressure. At cquilibrium partial pressure of HNO_(3) is 2 atm. Calculate Kc in ("mole" //L)^(3) at 400 K.

K_(c) for the reaction N_(2)O(g)hArr2NO_(2)(g) is 4.63xx10^(-3) at 25^(2)C . a. What is the value of K_(p) at this temperature? b. At 25^(@)C , if the partial pressure of N_(2)O_(4)(g) at equilibrium is 0.2 atm, calculate equilibrium pressure of NO_(2)(g)