`COCl_(2)` gas dissociates according to the equation, `COCl_(2)hArrCO(g)+Cl_(2)(g)`. When heated to 700 K the density of the gas mixture at 1.16 atm and at equilibrium is `1.16 g//litre` The degree of dissociation of `COCl_(2)` at 700K is :

For the reaction CO(g)+Cl_(2)(g)hArrCOCl_(2)(g) the value of (K_(c)/(K_(P))) is equal to :

2.8 g of a gas at 1atm and 273K occupies a volume of 2.24 litres. The gas can not be:

For the equilibrium SO_(2)Cl_(2)(g)hArrSO_(2)(g)+Cl_(2)(g) , what is the temperature at which (K_(p)(atm))/(K_(c)(M))=3 ?

At 200^(@)C PCl_(5) dissociates as follows : PCl_(5)(g0hArrPCl_(3)(g)+Cl_(2)(g) It was found that the equilibrium vapours are 62 times as heavy as hydreogen .The degree of dissociation of PCl_(5) at 200^(@)C is nearly :

For the reaction H_(2)(g)+CO(g)hArrCO(g)+H_(2)O(g), if the initial concentration of [H_(2)]=[CO_(2)] and x moles /litres of hydrogen is consummed at equilibrium , the correct expression of K_(p) is :

At certain temperature compound AB_(2)(g) dissociates accoring to the reacation 2AB_(2)(g) hArr2AB (g)+B_(2)(g) With degree of dissociation alpha Which is small compared with unity, the expression of K_(p) in terms of alpha and initial pressure P is :

For the dissociation reaction N_(2)O_($) (g)hArr 2NO_(2)(g) , the degree of dissociation (alpha) interms of K_(p) and total equilibrium pressure P is:

AB_(3)(g) is dissociates as AB_(3)(g)hArrAB_(@)(g)+(1)/(2)B_(@)(g) When the initial pressure of AB_(3) is800 torr and the pressure developed at equilibrium is 900 torr , what fraction of AB_(3)(g) is dissociated?

For the reaction 2A(g)hArrB(g)+3C(g), at a given temperature , K_(c)=16. What must be the volume of the flask , if a mixture of 2 mole each of A,B and C exist in equilibrium ?