For `I_(2)(g) hArr 2I(g), K_(p)=1.79xx10^(-10)`. The partial pressure of `I_(2)=1.0` atm and `I=0.5xx10^(-6)` atm after `50 min`. Comment on the status of equilibrium process.

For 2SO_(2)(g)+O_(2)(g) hArr 2SO_(3)(g),K_(p)=3.4 . At an instant, the partial pressures of SO_(2), O_(2) and SO_(3) were found to be 0.41 atm, 0.16 atm and 0.57 atm respectively. Comment on the status of equilibrium process.

For the reaction A_(2)(g) + 2B_(2)hArr2C_(2)(g) the partial pressure of A_(2) and B_(2) at equilibrium are 0.80 atm and 0.40 atm respectively.The pressure of the system is 2.80 atm. The equilibrium constant K_(p) will be

Consider the heterogeneous equilibrium CaCO_3(s) hArr CaO(s) +CO_2(g) k_p=4 xx 10^(-2) atm ……….(i) C(s) +CO_2(g) hArr 2CO(g) K_p=2.0 atm ………(ii) Calculate the partial pressure of CO(g) when CaCO_3 and C are mixed and allowed to attain equilibrium at the temperature for which the above two equilibria have been studied.

For the reaction C(s)+CO_(2)(g) hArr 2CO(g) , the partial pressure of CO_(2) and CO is 2.0 and 4.0 atm, respectively, at equilibrium. The K_(p) of the reaction is

The K_(p) value for the reaction. H_(2) +I_(2) hArr 2Hi at 460^(@)C is 49. If the initial pressure of H_(2) " and " I_(2) is 0.5 atm respectively , what will be the partial pressure of H_(2) at equilibrium ?

The K_(p) values for the reaction, H_(2)+I_(2)hArr2HI , at 460^(@)C is 49 . If the initial pressure of H_(2) and I_(2) is 0.5atm respectively, determine the partial pressure of each gas at equilibrium.

For COCl_(2)(g) hArr CO(g) +Cl_(2)(g), K_(p)=8xx10^(-8) atm. units at a certain temperature. Find the degree of dissociation of COCl_(2) at given temperature if the equilibrium pressure is 2.0 atm.

In the equilibrium 2SO_(2)(g)+O_(2)(g)hArr2SO_(3)(g) , the partial pressure of SO_(2),O_(2) and SO_(3) are 0.662,0.10 and 0.331 atm respectively . What should be the partial pressure of Oxygen so that the equilibrium concentrations of SO_(3) are equal ?