A `20` litre container at `400 K` contains `CO_(2) (g)` at pressure `0.4 atm` and an excess of `SrO` (neglect the volume of solid `SrO`). The volume of the container, when pressure of `CO_(2)` attains its maximum value, will be:
(Given that: `SrCO_(3)(s) hArr SrO(s) +CO_(2)(g)K_(p) =1.6 atm`)

A 20 liter container at 400 contains CO_(2)(g) at pressure 0.4 atm and an excess of SrO (neglect the volume of solid SrO). The volume of the container is now decreased by moving the movable piston fitted in the container. The maximum volume of the container, when pressure of CO_(2) attains Its maximum value will be : Given that : SrCO_(3)(S)hArrSrO(S)+CO_(2)(g) K_(p)=1.6 atm

A 20 litre container at 400 K contains CO_2 (g) at pressure 0.4 atm and an excess of SrO (neglect the volume of solid SrO). the volume of the container is now decreased by moving the movable piston fitted in the container. The maximum volume of the container, when pressure of CO_2 attains its maximum value, will be- (Given that: SrCO_3(s) K_p =1.6 atm

A 20 litre container at 400 K contains CO_2(g) at pressure 0.4 atm and an excess of SrO (neglect the volume of solid SrO) . The volume of the containers is now decreased by moving the movable piston fifted in the container . The maximum volume of the container , when pressure of CO_2 attains its maximum value , will be (Given that : SrCO_3(s) hArr SrO(s) +CO_2(g) , K_p = 1.6 atm)

A 20 litre container at 400 K contains CO_(2) gas at a pressure of 0.4 atm and an excess of solid SrO and solid SrCO_(3) (neglect the volume of the solids). The volume of the container is now gradually decreased by moving the piston fitted in the container. The volume of the container, when the pressure of CO_(2) attains its maximum value is (Given that SrCO_(3)(s) iff SrO(s)+CO_(2)(g), K_(p)=1.6 atm at 400K)