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 rach of A,B and C exist in equilibrium ?

For the reaction 3A(g)+B(g) hArr 2C(g) at a given temperature , K_c=9.0 .What must be the volume of the flask, if a mixture of 2.0 mol each of A, B and C exist in equilibrium ?

For the reaction 3A(g)+B(g) hArr 2C(g) at a given temperature, K_c =9.0 what must be the volume (in L) of the flask , if a mixture of 2.0 mol each of A,B and C exist in equilibrium ?

For the reaction A(g)hArrB(g)+C(g) At 300K , the average molecular weight of the equilibrium mixture is 83g//"mol" . If atomic weight of A, B and C are 100, 60 and 40 gram/mol respectively, then the number of moles of 'C' present at equilibrium in a reaction starting with 10 moles of A is

For the reaction (1)and(2) A(g)hArrB(g)+C(g) X(g) hArr2y(g) Given , K_(p1):K_(p2)=9:1 If the degree of dissocition of A(g) and X(g) be same then the toal pressure at equilibrium (1)and(2) are in the ratio:

For the hypothetical reaction, 2A(s)+B(g) hArr 3C(g) What is the equilibrium expression ?

For the reaction 2A(g)+B(g) hArr 3C(g)+4D(g) ,brgt Two moles each of A and B were taken into a 1L flask. The following must always be true when the system attained equilibrium

K_(c) for the reaction, A(l)+2B(s)+3C(g)hArr 2D(g)+2E(g)" at "27^(@)C is 10^(-3)M . K_(P) at this temperature is