Use Table 16.1 to calculate ΔS° for each of the following reactions.
(a)
(c)
(a)
Interpretation:
The entropy change (
Concept introduction:
Entropy is defined as the ratio of thermal energy to the temperature which is unavailable for work done. It is also defined as the measure of disorder of molecule of a system. It is an extensive property and state function.
Entropy is related with the number of microstates for a system and microstate is defined as the number of ways for the system to be arranged.
The standard entropy change at room temperature is equal to the difference between the standard entropy of reactant and standard entropy of product.
Answer to Problem 20QAP
Explanation of Solution
Given process is:
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 value of standard entropy for
The value of standard entropy for
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, we get:
(b)
Interpretation:
The entropy change (
Concept introduction:
Entropy is defined as the ratio of thermal energy to the temperature which is unavailable for work done. It is also defined as the measure of disorder of molecule of a system. It is an extensive property and state function.
Entropy is related with the number of microstates for a system and microstate is defined as the number of ways for the system to be arranged.
The standard entropy change at room temperature is equal to the difference between the standard entropy of reactant and standard entropy of product.
Answer to Problem 20QAP
Explanation of Solution
Given process is:
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 value of standard entropy for
The value of standard entropy for
The value of standard entropy for
The value of standard entropy for
The value of standard entropy for is
The value of standard entropy for
Put the values, we get:
(c)
Interpretation:
The entropy change (
Concept introduction:
Entropy is defined as the ratio of thermal energy to the temperature which is unavailable for work done. It is also defined as the measure of disorder of molecule of a system. It is an extensive property and state function.
Entropy is related with the number of microstates for a system and microstate is defined as the number of ways for the system to be arranged.
The standard entropy change at room temperature is equal to the difference between the standard entropy of reactant and standard entropy of product.
Answer to Problem 20QAP
Explanation of Solution
Given process is:
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 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, we get:
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Chapter 16 Solutions
Chemistry: Principles and Reactions
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- Consider the following reaction at 100.0 °C: Al(s) + NaOH(aq) + H20(l) ⇄ Na[Al(OH)4](aq) + H2(g) A) Write a balanced equilibrium quotient (Qc) for the following reaction. B) If the pressure of this reaction is increased, which direction will the equilibrium shift? Why?arrow_forwardWrite the equilibrium constant expression for the following equation: SnO2(s) + 2 CO(g) <=> Sn(s) + 2 CO2 (g)arrow_forwardCalculate the value of Kp for the following reaction at 50°C: 2 H2 (g) + 2 1, (g) = 4 HI (g) = 5.02 x 10-2.arrow_forward
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