`C(s)+CO_(2)(g)hArr2CO(g) K_(p)=1atm`
`CaCO_(3)(s)hArrCaO(s)+CO_(2)(s) K_(p)=4xx10^(-2)`
Solid `C,CaO "and" CaCO_(3) "are mixed and allowed to attain equilibrium. Calculate final pressure of" CO`.

For the reaction : CaCO_(3) (s) hArr CaO (s) + CO_(2) (g)

For CaCO_(3)(s) hArr CaO(s)+CO_(2)(g), K_(c) is equal to …………..

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.

At a certain temperature , K_(p) for dissociation of solid CaCO_(3) is 4xx10^(-2) atm and for the reaction, C(s)+CO_(2) hArr 2CO is 2.0 atm, respectively. Calculate the pressure of CO at this temperature when solid C, CaO, CaCO_(3) are mixed and allowed to attain equilibrium.

For the reaction CaCO_(3(s)) hArr CaO_((s))+CO_(2(g))k_p is equal to

CaCO_3(s) hArr CaO(s) + CO_2(g), DeltaH =110 kJ The pressure of CO_2 :

For the reaction : CaCO_(3)(s) hArr CaO(s)+CO_(2)(g),K_(p)=1.16atm at 800^(@)C . If 20g of CaCO_(3) were kept in a 10 litre vessel at 800^(@)C , the amount of CaCO_(3) remained at equilibrium is :

At 27^(@)C, K_(p) value for the reaction CaCO_(3)(s) hArr CaO (s) + CO_(2)(g) , is 0.1 atm. K_(C) value for this reaction is

For the reaction CaCO_(3)(s)hArrCaO(s)+CO_(2)(g) the equilibrium amount of CO_(2) can be increased by :