Interpretation:
The standard free energy change for the given equilibrium reaction and initial concentrations at
Concept introduction:
For a general
The relation between the free energy change and the standard free energy change is as follows:
Here,
The value of
The value of
The value of
Answer to Problem 56AP
Solution:
a)
b)
c)
d)
Explanation of Solution
a)
The given reaction for which
Theconcentration of pure liquids and pure solids istaken as unity. Therefore, the reaction quotient for the above reaction will be represented as follows:
The relation between the free energy change and the standard free energy change is as follows:
In this case, the given concentrations are equilibrium concentrations at
Thevalue of
Thus, the above expression is reduced to the expression, which is as follows:
Substitute all the values in the above expression as follows:
On further calculation, the standard free energy change will be calculated as follows:
Thus,
b)
The given reaction for which
The concentration of pure liquids and pure solids istaken as unity. Therefore, the reaction quotient for the above reaction will be represented as follows:
The relation between the free energy change and the standard free energy change is as follows:
Thus,
c)
The given reaction for which
The concentration of pure liquids and pure solids istaken as unity. Therefore, the reaction quotient for the above reaction will be represented as follows:
The relation between the free energy change and the standard free energy change is as follows:
Thus,
d)
The given reaction for which
The concentration of pure liquids and pure solids istaken as unity. Therefore, the reaction quotient for the above reaction will be represented as follows:
The relation between the free energy change and the standard free energy change is as follows:
Thus,
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Chapter 18 Solutions
Chemistry
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