Equilibrium constant for a reaction can be obtained by kinetics approach or by thermodynamics approch. While from kinetics approach at equililbrium, the rate of forward and backward will be same, from thermodynamics approach Gibbs free energy will be minimized at equilibrium. Using this information and following thermodynamics values, answer the question that follow: `DeltaG_(f)^(@)A(g)`=-200kcal/mole `DeltaG_(f)^(@)B(g)` =-320 kcal/mole `DeltaG_(f)^(@)C(g)`=-300kcal/mole `DeltaG_(f)^(@)D(l)`=-224.606 kcal/mole `DeltaG_(f)^(@)D(g)`= -226.9.9 kcal/ mole, All values at 500K Calculate equilibrium concentration of B(g) if A(g) at 10 bar, B(g) at 2 bar,C(g) at 20 bar is mixed with excess liquid D such that following equilbrium gets established at 500K: `A(g) B(g)iffC(g)+D(g)`A. 2MB. `(2)/(41.57)`C. `1M`D. `(1)/(41.57)`

Equilibrium constant for a reaction can be obtained by kinetics approa

1.	Equilibrium constant for a reaction can be obtained by kinetics approach or by thermodynamics approch. While from kinetics approach at equililbrium, the rate of forward and backward will be same, from thermodynamics approach Gibbs free energy will be minimized at equilibrium. Using this information and following thermodynamics values, answer the question that follow: `DeltaG_(f)^(@)A(g)`=-200kcal/mole `DeltaG_(f)^(@)B(g)` =-320 kcal/mole `DeltaG_(f)^(@)C(g)`=-300kcal/mole `DeltaG_(f)^(@)D(l)`=-224.606 kcal/mole `DeltaG_(f)^(@)D(g)`= -226.9.9 kcal/ mole, All values at 500K Calculate equilibrium concentration of B(g) if A(g) at 10 bar, B(g) at 2 bar,C(g) at 20 bar is mixed with excess liquid D such that following equilbrium gets established at 500K: `A(g) B(g)iffC(g)+D(g)`A. 2MB. `(2)/(41.57)`C. `1M`D. `(1)/(41.57)`
Answer» Correct Answer - b

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