(a)
Interpretation:
Calculate the equilibrium constant at 1000 K with the help of given moles of reactant and products for the equilibrium reaction.
Concept introduction:
The Gibb’s equation of
With the help of this equation we can predict the change in
Here ‘a’ represent the active mass and ‘P’ represents the partial pressure. The relation between equilibrium constant and
Here:
- R = 8.314 J / mol .K
- T = temperature in Kelvin
(b)
Interpretation:
Calculate theGibbs free energy change
Concept introduction:
The Gibb’s equation of thermodynamic purposed a relation between
With the help of this equation we can predict the change in
Here ‘a’ represent the active mass and ‘P’ represents the partial pressure. The relation between equilibrium constant and
Here:
- R = 8.314 J / mol .K
- T = temperature in Kelvin
(c)
Interpretation:
Interpret the direction of reaction for the given moles of reactant and product at 1000 K.
Concept introduction:
The Gibb’s equation of thermodynamic purposed a relation between
With the help of this equation we can predict the change in
Here ‘a’ represent the active mass and ‘P’ represents the partial pressure. The relation between equilibrium constant and
Here:
- R = 8.314 J / mol .K
- T = temperature in Kelvin
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EP GENERAL CHEMISTRY-MOD.MASTERINGCHEM.
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