Chemistry & Chemical Reactivity
Chemistry & Chemical Reactivity
9th Edition
ISBN: 9781133949640
Author: John C. Kotz, Paul M. Treichel, John Townsend, David Treichel
Publisher: Cengage Learning
bartleby

Videos

Question
Book Icon
Chapter 18, Problem 84SCQ

(a)

Interpretation Introduction

Interpretation:

The  ΔSo(system) for reaction between NO(g) and Cl2(g) should be determined.

Concept introduction:

The universe consists of two parts, systems and surroundings. The entropy change for the universe is the sum of entropy change for the system and for surroundings.

  ΔSo(universe)= ΔSo(system)+ΔSo(surroundings)

The ΔSo(universe) should be greater than zero for a spontaneous process.

The  ΔSo(system) can be calculated by the following expression,

  ΔSo(system)=ΔrS°nS°(products)-nS°(reactants)

The ΔSo(surroundings) can be calculated by the following expression,

  ΔSo(surroundings)=rHoT

Here, ΔrH° is the enthalpy change for the reaction.

The Gibbs free energy or the free energy change is a thermodynamic quantity represented by ΔGo. It is related to entropy and entropy by the following expression,

  ΔGo= ΔHo- TΔSo

ΔGo is also related to the equilibrium constant K by the equation,

  ΔrGo= -RTlnKp

The rearranged expression is,

  Kp= eΔrGoRT

(a)

Expert Solution
Check Mark

Answer to Problem 84SCQ

The  ΔSo(system) for the reaction is 60.5 J/Kmol-rxn.

Explanation of Solution

The  ΔSo(system) for the reaction is calculated below.

Given:

Refer to Appendix L for the values of standard entropies.

The standard entropy of NOCl(g) is 261.8 J/Kmol.

The standard entropy of NO(g) is 210.76 J/Kmol.

The standard entropy of Cl2(g) is 223.08 J/Kmol.

The balanced chemical equation is:

  NO(g)+12Cl2(g)NOCl(g)

The  ΔSo(system) can be calculated by the following expression,

  ΔSo(system)=ΔrS°nS°(products)-nS°(reactants)=[(1 mol NOCl(g)/mol-rxn)S°[NOCl(g)]-[(1 mol NO(g)/mol-rxn)S°[NO(g)]+(0.5 mol Cl2(g)/mol-rxn)S°[Cl2(g)]]]

Substitute the values,

  ΔSo(system)[(1 mol NOCl(g)/mol-rxn)(261.8 J/K×mol)-[(1 mol NO(g)/mol-rxn)(210.76 J/K×mol)+(0.5 mol Cl2(g)/mol-rxn)(223.08 J/K×mol)]]ΔSo= -60.5 J/K×mol-rxn

(b)

Interpretation Introduction

Interpretation:

It should be identified that  ΔSo(system) changes with temperature or not.

Concept introduction:

The universe consists of two parts, systems and surroundings. The entropy change for the universe is the sum of entropy change for the system and for surroundings.

  ΔSo(universe)= ΔSo(system)+ΔSo(surroundings)

The ΔSo(universe) should be greater than zero for a spontaneous process.

The  ΔSo(system) can be calculated by the following expression,

  ΔSo(system)=ΔrS°nS°(products)-nS°(reactants)

The ΔSo(surroundings) can be calculated by the following expression,

  ΔSo(surroundings)=rHoT

Here, ΔrH° is the enthalpy change for the reaction.

The Gibbs free energy or the free energy change is a thermodynamic quantity represented by ΔGo. It is related to entropy and entropy by the following expression,

  ΔGo= ΔHo- TΔSo

ΔGo is also related to the equilibrium constant K by the equation,

  ΔrGo= -RTlnKp

The rearranged expression is,

  Kp= eΔrGoRT

(b)

Expert Solution
Check Mark

Answer to Problem 84SCQ

The value of ΔSo(system) changes with temperature.

Explanation of Solution

The entropy of the system is dependent upon temperature. Entropy of any system increases with increase in the temperature due to the heat which is added to the system at higher temperatures.

(c)

Interpretation Introduction

Interpretation:

It should be identified that ΔSo(surroundings) changes with temperature.

Concept introduction:

The universe consists of two parts, systems and surroundings. The entropy change for the universe is the sum of entropy change for the system and for surroundings.

  ΔSo(universe)= ΔSo(system)+ΔSo(surroundings)

The ΔSo(universe) should be greater than zero for a spontaneous process.

The  ΔSo(system) can be calculated by the following expression,

  ΔSo(system)=ΔrS°nS°(products)-nS°(reactants)

The ΔSo(surroundings) can be calculated by the following expression,

  ΔSo(surroundings)=rHoT

Here, ΔrH° is the enthalpy change for the reaction.

The Gibbs free energy or the free energy change is a thermodynamic quantity represented by ΔGo. It is related to entropy and entropy by the following expression,

  ΔGo= ΔHo- TΔSo

ΔGo is also related to the equilibrium constant K by the equation,

  ΔrGo= -RTlnKp

The rearranged expression is,

  Kp= eΔrGoRT

(c)

Expert Solution
Check Mark

Answer to Problem 84SCQ

The ΔSo(surroundings) for any reaction changes with temperature.

Explanation of Solution

The ΔSo(surroundings) can be calculated by the following expression,

  ΔSo(surroundings)rHoT

Here, ΔrHo is the enthalpy change for the reaction.

Thus, ΔSo(surroundings) is inversely related to temperature.

(d)

Interpretation Introduction

Interpretation:

It should be identified that ΔSo(surroundings) changes with increase in temperature or not.

Concept introduction:

The universe consists of two parts, systems and surroundings. The entropy change for the universe is the sum of entropy change for the system and for surroundings.

  ΔSo(universe)= ΔSo(system)+ΔSo(surroundings)

The ΔSo(universe) should be greater than zero for a spontaneous process.

The  ΔSo(system) can be calculated by the following expression,

  ΔSo(system)=ΔrS°nS°(products)-nS°(reactants)

The ΔSo(surroundings) can be calculated by the following expression,

  ΔSo(surroundings)=rHoT

Here, ΔrH° is the enthalpy change for the reaction.

The Gibbs free energy or the free energy change is a thermodynamic quantity represented by ΔGo. It is related to entropy and entropy by the following expression,

  ΔGo= ΔHo- TΔSo

ΔGo is also related to the equilibrium constant K by the equation,

  ΔrGo= -RTlnKp

The rearranged expression is,

  Kp= eΔrGoRT

(d)

Expert Solution
Check Mark

Answer to Problem 84SCQ

The value of ΔSo(universe) changes with an increase in temperature.

Explanation of Solution

The entropy change for the universe is the sum of entropy change for the system and for surroundings.

  ΔSo(universe)= ΔSo(system)+ΔSo(surroundings)

Both ΔSo(system) and ΔSo(surroundings) are dependent upon temperatures. Thus, the value of ΔSo(universe) changes with an increase in temperature.

(e)

Interpretation Introduction

Interpretation:

It should be identified that does exothermic reaction will always results in positive ΔSo(universe) value.

Concept introduction:

The universe consists of two parts, systems and surroundings. The entropy change for the universe is the sum of entropy change for the system and for surroundings.

  ΔSo(universe)= ΔSo(system)+ΔSo(surroundings)

The ΔSo(universe) should be greater than zero for a spontaneous process.

The  ΔSo(system) can be calculated by the following expression,

  ΔSo(system)=ΔrS°nS°(products)-nS°(reactants)

The ΔSo(surroundings) can be calculated by the following expression,

  ΔSo(surroundings)=rHoT

Here, ΔrH° is the enthalpy change for the reaction.

The Gibbs free energy or the free energy change is a thermodynamic quantity represented by ΔGo. It is related to entropy and entropy by the following expression,

  ΔGo= ΔHo- TΔSo

ΔGo is also related to the equilibrium constant K by the equation,

  ΔrGo= -RTlnKp

The rearranged expression is,

  Kp= eΔrGoRT

(e)

Expert Solution
Check Mark

Answer to Problem 84SCQ

The exothermic reaction does not necessarily leads to a positive value of ΔSo(universe).

Explanation of Solution

The exothermic reaction have negative value of free energy change which means that the ΔSo(surroundings) will be positive. However, if the value of ΔSo(system) is negative and has greater magnitude than the ΔSo(surroundings) than the sign of ΔSo(universe) is negative. The reaction in such a case is non-spontaneous.

(f)

Interpretation Introduction

Interpretation:

It should be identified that reaction of NO(g) and Cl2(g) is spontaneous or not.

Concept introduction:

The universe consists of two parts, systems and surroundings. The entropy change for the universe is the sum of entropy change for the system and for surroundings.

  ΔSo(universe)= ΔSo(system)+ΔSo(surroundings)

The ΔSo(universe) should be greater than zero for a spontaneous process.

The  ΔSo(system) can be calculated by the following expression,

  ΔSo(system)=ΔrS°nS°(products)-nS°(reactants)

The ΔSo(surroundings) can be calculated by the following expression,

  ΔSo(surroundings)=rHoT

Here, ΔrH° is the enthalpy change for the reaction.

The Gibbs free energy or the free energy change is a thermodynamic quantity represented by ΔGo. It is related to entropy and entropy by the following expression,

  ΔGo= ΔHo- TΔSo

ΔGo is also related to the equilibrium constant K by the equation,

  ΔrGo= -RTlnKp

The rearranged expression is,

  Kp= eΔrGoRT

(f)

Expert Solution
Check Mark

Answer to Problem 84SCQ

The reaction is spontaneous at 298 K.

The reaction is not spontaneous at 700 K.

Explanation of Solution

The free energy change for the given reaction is calculated below.

Given:

Refer to Appendix L for the values of standard entropies.

The standard enthalpy of NOCl(g) is 51.71 kJ/mol.

The standard enthalpy of NO(g) is 90.29 kJ/mol.

The standard enthalpy of Cl2(g) is 0 kJ/mol.

The balanced chemical equation is:

  NO(g)+12Cl2(g)NOCl(g)

The ΔrHo can be calculated by the following expression,

  ΔrH°=fH°(products)fH°(reactants)=[(1 mol NOCl(g)/mol-rxn)ΔfH°[NOCl(g)]-[(1 mol NO(g)/mol-rxn)ΔfH°[NO(g)]+(0.5 mol Cl2(g)/mol-rxn)ΔfH°[Cl2(g)]]]

Substitute the values,

  ΔrH°=[(1 mol NOCl(g)/mol-rxn)(51.71 kJ/mol)-[(1 mol NO(g)/mol-rxn)(90.29 kJ/mol)+(0.5 mol Cl2(g)/mol-rxn)(0 kJ/mol)]]ΔrH°= -38.58 J/K×mol-rxn

Now,

  ΔGo=ΔHo-TΔSo

Substitute the values at temperature 298 K,

  ΔGo=-38.58 kJ/mol-rxn-[(298K)(-60.5 J/K×mol-rxn)](1 kJ1000 J)=-20.551 kJ/mol-rxn

Thus, the reaction is spontaneous at 298 K.

Substitute the values at temperature 700 K,

ΔGo= -38.58 kJ/mol-rxn-[(700K)(-60.5 J/K×mol-rxn)](1 kJ1000 J)= +3.77 kJ/mol-rxn

Thus, the reaction is not spontaneous at 700 K.

Want to see more full solutions like this?

Subscribe now to access step-by-step solutions to millions of textbook problems written by subject matter experts!

Chapter 18 Solutions

Chemistry & Chemical Reactivity

Ch. 18.4 - Without looking up their standard entropies in...Ch. 18.4 - Without doing any calculations, predict the sign...Ch. 18.4 - Calculate rS for the following reaction at 25 C....Ch. 18.5 - Based on rH and rS, predict the spontaneity of the...Ch. 18.5 - Prob. 1RCCh. 18.5 - Prob. 2RCCh. 18.5 - Prob. 3RCCh. 18.6 - Prob. 1RCCh. 18.6 - Prob. 2RCCh. 18.7 - Prob. 1CYUCh. 18.7 - Prob. 2CYUCh. 18.7 - Oxygen was first prepared by Joseph Priestley...Ch. 18.7 - Prob. 4CYUCh. 18.7 - Prob. 5CYUCh. 18.7 - Prob. 6CYUCh. 18.7 - Prob. 1RCCh. 18.7 - Prob. 2RCCh. 18.7 - Prob. 3RCCh. 18.7 - Consider the hydrolysis reactions of creatine...Ch. 18.7 - Prob. 2QCh. 18.A - The decomposition of diamond to graphite...Ch. 18.A - It has been demonstrated that buckminsterfullerene...Ch. 18 - Which substance has the higher entropy? (a) dry...Ch. 18 - Which substance has the higher entropy? (a) a...Ch. 18 - Use S values to calculate the standard entropy...Ch. 18 - Use S values to calculate the standard entropy...Ch. 18 - Calculate the standard entropy change for the...Ch. 18 - Calculate the standard entropy change for the...Ch. 18 - Calculate the standard entropy change for the...Ch. 18 - Calculate the standard entropy change for the...Ch. 18 - Is the reaction Si(s) + 2 Cl2(g) SiCl4(g)...Ch. 18 - Is the reaction Si(s) + 2 H2(g) SiH4(g)...Ch. 18 - Calculate S(universe) for the decomposition of 1...Ch. 18 - Calculate S(universe) for the formation of 1 mol...Ch. 18 - Classify each of the reactions according to one of...Ch. 18 - Classify each of the reactions according to one of...Ch. 18 - Using values of fH and S, calculate rG for each of...Ch. 18 - Using values of fH and S, calculate rG for each of...Ch. 18 - Using values of fH and S, calculate the standard...Ch. 18 - Using values of fH and S, calculate the standard...Ch. 18 - Using values of fG, calculate rG for each of the...Ch. 18 - Using values of fG, calculate rG for each of the...Ch. 18 - For the reaction BaCO3(s) BaO(s) + CO2(g), rG =...Ch. 18 - For the reaction TiCl2(s) + Cl2(g) TiCl4(), rG =...Ch. 18 - Determine whether the reactions listed below are...Ch. 18 - Determine whether the reactions listed below are...Ch. 18 - Heating some metal carbonates, among them...Ch. 18 - Calculate rH and rS for the reaction of tin(IV)...Ch. 18 - The standard free energy change, rG, for the...Ch. 18 - Prob. 28PSCh. 18 - Calculate rG at 25 C for the formation of 1.00 mol...Ch. 18 - Prob. 30PSCh. 18 - Prob. 31PSCh. 18 - Prob. 32PSCh. 18 - Compare the compounds in each set below and decide...Ch. 18 - Using standard entropy values, calculate rS for...Ch. 18 - About 5 billion kilograms of benzene, C6H6, are...Ch. 18 - Hydrogenation, the addition of hydrogen to an...Ch. 18 - Is the combustion of ethane, C2H6, product-favored...Ch. 18 - Prob. 38GQCh. 18 - When vapors from hydrochloric acid and aqueous...Ch. 18 - Calculate S(system), S(surroundings), and...Ch. 18 - Methanol is now widely used as a fuel in race...Ch. 18 - The enthalpy of vaporization of liquid diethyl...Ch. 18 - Calculate the entropy change, rS, for the...Ch. 18 - Using thermodynamic data, estimate the normal...Ch. 18 - Prob. 45GQCh. 18 - When calcium carbonate is heated strongly, CO2 gas...Ch. 18 - Sodium reacts violently with water according to...Ch. 18 - Yeast can produce ethanol by the fermentation of...Ch. 18 - Elemental boron, in the form of thin fibers, can...Ch. 18 - Prob. 50GQCh. 18 - Prob. 51GQCh. 18 - Estimate the boiling point of water in Denver,...Ch. 18 - The equilibrium constant for the butane ...Ch. 18 - A crucial reaction for the production of synthetic...Ch. 18 - Calculate rG for the decomposition of sulfur...Ch. 18 - Prob. 56GQCh. 18 - A cave in Mexico was recently discovered to have...Ch. 18 - Wet limestone is used to scrub SO2 gas from the...Ch. 18 - Sulfur undergoes a phase transition between 80 and...Ch. 18 - Calculate the entropy change for dissolving HCl...Ch. 18 - Some metal oxides can be decomposed to the metal...Ch. 18 - Prob. 62ILCh. 18 - Prob. 63ILCh. 18 - Prob. 64ILCh. 18 - Titanium(IV) oxide is converted to titanium...Ch. 18 - Cisplatin [cis-diamminedichloroplatinum(II)] is a...Ch. 18 - Prob. 67SCQCh. 18 - Explain why each of the following statements is...Ch. 18 - Decide whether each of the following statements is...Ch. 18 - Under what conditions is the entropy of a pure...Ch. 18 - Prob. 71SCQCh. 18 - Consider the formation of NO(g) from its elements....Ch. 18 - Prob. 73SCQCh. 18 - The normal melting point of benzene, C6H6, is 5.5...Ch. 18 - Prob. 75SCQCh. 18 - For each of the following processes, predict the...Ch. 18 - Heater Meals are food packages that contain their...Ch. 18 - Prob. 78SCQCh. 18 - Prob. 79SCQCh. 18 - Prob. 80SCQCh. 18 - Iodine, I2, dissolves readily in carbon...Ch. 18 - Prob. 82SCQCh. 18 - Prob. 83SCQCh. 18 - Prob. 84SCQCh. 18 - Prob. 85SCQCh. 18 - Prob. 86SCQCh. 18 - The Haber-Bosch process for the production of...Ch. 18 - Prob. 88SCQ
Knowledge Booster
Background pattern image
Chemistry
Learn more about
Need a deep-dive on the concept behind this application? Look no further. Learn more about this topic, chemistry and related others by exploring similar questions and additional content below.
Similar questions
SEE MORE QUESTIONS
Recommended textbooks for you
Text book image
Chemistry for Engineering Students
Chemistry
ISBN:9781337398909
Author:Lawrence S. Brown, Tom Holme
Publisher:Cengage Learning
Text book image
Chemistry: Principles and Practice
Chemistry
ISBN:9780534420123
Author:Daniel L. Reger, Scott R. Goode, David W. Ball, Edward Mercer
Publisher:Cengage Learning
Text book image
Chemistry: The Molecular Science
Chemistry
ISBN:9781285199047
Author:John W. Moore, Conrad L. Stanitski
Publisher:Cengage Learning
Text book image
Principles of Modern Chemistry
Chemistry
ISBN:9781305079113
Author:David W. Oxtoby, H. Pat Gillis, Laurie J. Butler
Publisher:Cengage Learning
Text book image
Chemistry by OpenStax (2015-05-04)
Chemistry
ISBN:9781938168390
Author:Klaus Theopold, Richard H Langley, Paul Flowers, William R. Robinson, Mark Blaser
Publisher:OpenStax
Text book image
Chemistry: An Atoms First Approach
Chemistry
ISBN:9781305079243
Author:Steven S. Zumdahl, Susan A. Zumdahl
Publisher:Cengage Learning
The Laws of Thermodynamics, Entropy, and Gibbs Free Energy; Author: Professor Dave Explains;https://www.youtube.com/watch?v=8N1BxHgsoOw;License: Standard YouTube License, CC-BY