
(a)
Interpretation:
The value of
Concept Introduction:
The mathematical expression for the standard entropy value at room temperature is:
Where, n and p represents the coefficients of reactants and products in the balanced chemical equation.
The mathematical expression for the standard enthalpy change value at room temperature is:
Where, n and p represents the coefficients of reactants and products in the balanced chemical equation.
Spontaneity depends upon the temperature and also depends upon the sign of free energy change.
The mathematical expression for
If both
When the magnitude of
Therefore, reaction is non- spontaneous at low temperature and spontaneous at high temperature.
(a)

Answer to Problem 2E
Explanation of Solution
The given reaction is:
The value of standard entropy for
The value of standard entropy for
The value of standard entropy for
The value of standard entropy for
Put the values, in below formula.
The value of standard enthalpy for
The value of standard enthalpy for
The value of standard enthalpy for
The value of standard enthalpy for
Put the values, in below formula.
(b)
Interpretation:
The temperature which favor the formation of product should be determined by considering standard conditions and,
Concept Introduction:
The mathematical expression for the standard entropy value at room temperature is:
Where, n and p represents the coefficients of reactants and products in the balanced chemical equation.
The mathematical expression for the standard enthalpy change value at room temperature is:
Where, n and p represents the coefficients of reactants and products in the balanced chemical equation.
Spontaneity depends upon the temperature and also depends upon the sign of free energy change.
The mathematical expression for
If both
When the magnitude of
Therefore, reaction is non- spontaneous at low temperature and spontaneous at high temperature.
(b)

Answer to Problem 2E
The temperature which favors the formation of product is
Explanation of Solution
The given reaction is:
From part (a):
Here, sign of
Put the values,
Now,
Let
Since, 1 Kilojoule = 1000 Joule
The process is spontaneous when
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Chapter 18 Solutions
EBK CHEMICAL PRINCIPLES
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