Student Solutions Manual for Zumdahl/Zumdahl/DeCoste?s Chemistry, 10th Edition
Student Solutions Manual for Zumdahl/Zumdahl/DeCoste?s Chemistry, 10th Edition
10th Edition
ISBN: 9781305957510
Author: ZUMDAHL, Steven S.; Zumdahl, Susan A.; DeCoste, Donald J.
Publisher: Cengage Learning
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Chapter 9, Problem 28E

Give the expected hybridization of the central atom for the molecules or ions in Exercises 82 and 88 from Chapter 3.

(a-I)

Expert Solution
Check Mark
Interpretation Introduction

Interpretation: The expected hybridization of the central atom, for the given species, is to be determined.

Concept introduction: The following steps are to be followed to determine the hybridization and the molecular structure of a given compound,

  • The central atom is identified.
  • Its valence electrons are determined.
  • 1e is added to the total number of valence electrons for each monovalent atom present.
  • The total number obtained is divided by 2, to find the number of electron pairs.
  • This further gives us the hybridization of the given compound.

For an atom, present in the structure of a compound, the sum of the number of bonded atoms and the number of lone pairs present on it gives its steric number. The value of the steric number gives us the hybridization of the atom.

To determine: The expected hybridization of the central atom in POCl3.

Answer to Problem 28E

Answer

The given compound is sp3 hybridized.

Explanation of Solution

The atomic number of phosphorous is 15 and its electronic configuration is,

1s22s22p63s23p3

The valence electron of phosphorous is 5

The formula of number of electron pairs is,

X=V+M±C2

Where,

  • X is number of electron pairs.
  • V is valence electrons of central atom.
  • M is number of monovalent atoms.
  • C is charge on compound.

The number of electron pairs is,

X=V+M±C2X=5+32=4

This means that the central atom shows sp3 hybridization and should have a tetrahedral geometry.

Conclusion

The geometry of a given compound can be predicted using the hybridization of the central atom present.

(a-II)

Expert Solution
Check Mark
Interpretation Introduction

Interpretation: The expected hybridization of the central atom, for the given species, is to be determined.

Concept introduction: The following steps are to be followed to determine the hybridization and the molecular structure of a given compound,

  • The central atom is identified.
  • Its valence electrons are determined.
  • 1e is added to the total number of valence electrons for each monovalent atom present.
  • The total number obtained is divided by 2, to find the number of electron pairs.
  • This further gives us the hybridization of the given compound.

For an atom, present in the structure of a compound, the sum of the number of bonded atoms and the number of lone pairs present on it gives its steric number. The value of the steric number gives us the hybridization of the atom.

To determine: The expected hybridization of the central atom in SO42.

Answer to Problem 28E

Answer

The given compound is sp3 hybridized.

Explanation of Solution

The atomic number of sulfur is 16 and its electronic configuration is,

1s22s22p63s23p4

The valence electron of sulfur is 6

The formula of number of electron pairs is,

X=V+M±C2

Where,

  • X is number of electron pairs.
  • V is valence electrons of central atom.
  • M is number of monovalent atoms.
  • C is charge on compound.

The number of electron pairs is,

X=V+M±C2X=6+22=4

This means that the central atom shows sp3 hybridization and should have a tetrahedral geometry.

Conclusion

The geometry of a given compound can be predicted using the hybridization of the central atom present.

(a-III)

Expert Solution
Check Mark
Interpretation Introduction

Interpretation: The expected hybridization of the central atom, for the given species, is to be determined.

Concept introduction: The following steps are to be followed to determine the hybridization and the molecular structure of a given compound,

  • The central atom is identified.
  • Its valence electrons are determined.
  • 1e is added to the total number of valence electrons for each monovalent atom present.
  • The total number obtained is divided by 2, to find the number of electron pairs.
  • This further gives us the hybridization of the given compound.

For an atom, present in the structure of a compound, the sum of the number of bonded atoms and the number of lone pairs present on it gives its steric number. The value of the steric number gives us the hybridization of the atom.

To determine: The expected hybridization of the central atom in XeO4.

Answer to Problem 28E

Answer

The given compound is sp3 hybridized.

Explanation of Solution

Explanation:

The atomic number of xenon is 54 and its electronic configuration is,

1s22s22p63s23p63d104s24p64d105s25p6

The valence electron of xenon is 8

The formula of number of electron pairs is,

X=V+M±C2

Where,

  • X is number of electron pairs.
  • V is valence electrons of central atom.
  • M is number of monovalent atoms.
  • C is charge on compound.

The number of electron pairs is,

X=V+M±C2X=82=4

This means that the central atom shows sp3 hybridization and should have a tetrahedral geometry.

Conclusion

The geometry of a given compound can be predicted using the hybridization of the central atom present.

(a-IV)

Expert Solution
Check Mark
Interpretation Introduction

Interpretation: The expected hybridization of the central atom, for the given species, is to be determined.

Concept introduction: The following steps are to be followed to determine the hybridization and the molecular structure of a given compound,

  • The central atom is identified.
  • Its valence electrons are determined.
  • 1e is added to the total number of valence electrons for each monovalent atom present.
  • The total number obtained is divided by 2, to find the number of electron pairs.
  • This further gives us the hybridization of the given compound.

For an atom, present in the structure of a compound, the sum of the number of bonded atoms and the number of lone pairs present on it gives its steric number. The value of the steric number gives us the hybridization of the atom.

To determine: The expected hybridization of the central atom in PO43.

Answer to Problem 28E

Answer

The given compound is sp3 hybridized.

Explanation of Solution

The atomic number of phosphorous is 15 and its electronic configuration is,

1s22s22p63s23p3

The valence electron of phosphorous is 5

The formula of number of electron pairs is,

X=V+M±C2

Where,

  • X is number of electron pairs.
  • V is valence electrons of central atom.
  • M is number of monovalent atoms.
  • C is charge on compound.

The number of electron pairs is,

X=V+M±C2X=5+32=4

This means that the central atom shows sp3 hybridization and should have a tetrahedral geometry.

Conclusion

The geometry of a given compound can be predicted using the hybridization of the central atom present.

(a-V)

Expert Solution
Check Mark
Interpretation Introduction

Interpretation: The expected hybridization of the central atom, for the given species, is to be determined.

Concept introduction: The following steps are to be followed to determine the hybridization and the molecular structure of a given compound,

  • The central atom is identified.
  • Its valence electrons are determined.
  • 1e is added to the total number of valence electrons for each monovalent atom present.
  • The total number obtained is divided by 2, to find the number of electron pairs.
  • This further gives us the hybridization of the given compound.

For an atom, present in the structure of a compound, the sum of the number of bonded atoms and the number of lone pairs present on it gives its steric number. The value of the steric number gives us the hybridization of the atom.

To determine: The expected hybridization of the central atom in ClO4.

Answer to Problem 28E

Answer

The given compound is sp3 hybridized.

Explanation of Solution

The atomic number of chlorine is 17 and its electronic configuration is,

1s22s22p63s23p5

The valence electron of chlorine is 7

The formula of number of electron pairs is,

X=V+M±C2

Where,

  • X is number of electron pairs.
  • V is valence electrons of central atom.
  • M is number of monovalent atoms.
  • C is charge on compound.

The number of electron pairs is,

X=V+M±C2X=7+12=4

This means that the central atom shows sp3 hybridization and should have a tetrahedral geometry.

Conclusion

The geometry of a given compound can be predicted using the hybridization of the central atom present.

(b-I)

Expert Solution
Check Mark
Interpretation Introduction

Interpretation: The expected hybridization of the central atom, for the given species, is to be determined.

Concept introduction: The following steps are to be followed to determine the hybridization and the molecular structure of a given compound,

  • The central atom is identified.
  • Its valence electrons are determined.
  • 1e is added to the total number of valence electrons for each monovalent atom present.
  • The total number obtained is divided by 2, to find the number of electron pairs.
  • This further gives us the hybridization of the given compound.

For an atom, present in the structure of a compound, the sum of the number of bonded atoms and the number of lone pairs present on it gives its steric number. The value of the steric number gives us the hybridization of the atom.

To determine: The expected hybridization of the central atom in NF3.

Answer to Problem 28E

Answer

The given compound is sp3 hybridized.

Explanation of Solution

The atomic number of nitrogen is 7 and its electronic configuration is,

1s22s22p3

The valence electron of nitrogen is 5

The formula of number of electron pairs is,

X=V+M±C2

Where,

  • X is number of electron pairs.
  • V is valence electrons of central atom.
  • M is number of monovalent atoms.
  • C is charge on compound.

The number of electron pairs is,

X=V+M±C2X=5+32=4

This means that the central atom shows sp3 hybridization and should have a tetrahedral geometry.

Conclusion

The geometry of a given compound can be predicted using the hybridization of the central atom present.

(b-II)

Expert Solution
Check Mark
Interpretation Introduction

Interpretation: The expected hybridization of the central atom, for the given species, is to be determined.

Concept introduction: The following steps are to be followed to determine the hybridization and the molecular structure of a given compound,

  • The central atom is identified.
  • Its valence electrons are determined.
  • 1e is added to the total number of valence electrons for each monovalent atom present.
  • The total number obtained is divided by 2, to find the number of electron pairs.
  • This further gives us the hybridization of the given compound.

For an atom, present in the structure of a compound, the sum of the number of bonded atoms and the number of lone pairs present on it gives its steric number. The value of the steric number gives us the hybridization of the atom.

To determine: The expected hybridization of the central atom in SO32.

Answer to Problem 28E

Answer

The given compound is sp3 hybridized.

Explanation of Solution

The atomic number of sulfur is 16 and its electronic configuration is,

1s22s22p63s23p4

The valence electron of sulfur is 6

The formula of number of electron pairs is,

X=V+M±C2

Where,

  • X is number of electron pairs.
  • V is valence electrons of central atom.
  • M is number of monovalent atoms.
  • C is charge on compound.

The number of electron pairs is,

X=V+M±C2X=6+22=4

This means that the central atom shows sp3 hybridization and should have a tetrahedral geometry.

Conclusion

The geometry of a given compound can be predicted using the hybridization of the central atom present.

(b-III)

Expert Solution
Check Mark
Interpretation Introduction

Interpretation: The expected hybridization of the central atom, for the given species, is to be determined.

Concept introduction: The following steps are to be followed to determine the hybridization and the molecular structure of a given compound,

  • The central atom is identified.
  • Its valence electrons are determined.
  • 1e is added to the total number of valence electrons for each monovalent atom present.
  • The total number obtained is divided by 2, to find the number of electron pairs.
  • This further gives us the hybridization of the given compound.

For an atom, present in the structure of a compound, the sum of the number of bonded atoms and the number of lone pairs present on it gives its steric number. The value of the steric number gives us the hybridization of the atom.

To determine: The expected hybridization of the central atom in PO33.

Answer to Problem 28E

Answer

The given compound is sp3 hybridized.

Explanation of Solution

The atomic number of phosphorous is 15 and its electronic configuration is,

1s22s22p63s23p3

The valence electron of phosphorous is 5

The formula of number of electron pairs is,

X=V+M±C2

Where,

  • X is number of electron pairs.
  • V is valence electrons of central atom.
  • M is number of monovalent atoms.
  • C is charge on compound.

The number of electron pairs is,

X=V+M±C2X=5+32=4

This means that the central atom shows sp3 hybridization and should have a tetrahedral geometry.

Conclusion

The geometry of a given compound can be predicted using the hybridization of the central atom present.

(b-IV)

Expert Solution
Check Mark
Interpretation Introduction

Interpretation: The expected hybridization of the central atom, for the given species, is to be determined.

Concept introduction: The following steps are to be followed to determine the hybridization and the molecular structure of a given compound,

  • The central atom is identified.
  • Its valence electrons are determined.
  • 1e is added to the total number of valence electrons for each monovalent atom present.
  • The total number obtained is divided by 2, to find the number of electron pairs.
  • This further gives us the hybridization of the given compound.

For an atom, present in the structure of a compound, the sum of the number of bonded atoms and the number of lone pairs present on it gives its steric number. The value of the steric number gives us the hybridization of the atom.

To determine: The expected hybridization of the central atom in ClO3.

Answer to Problem 28E

Answer

The given compound is sp3 hybridized.

Explanation of Solution

The atomic number of chlorine is 17 and its electronic configuration is,

1s22s22p63s23p5

The valence electron of chlorine is 7

The formula of number of electron pairs is,

X=V+M±C2

Where,

  • X is number of electron pairs.
  • V is valence electrons of central atom.
  • M is number of monovalent atoms.
  • C is charge on compound.

The number of electron pairs is,

X=V+M±C2X=7+12=4

This means that the central atom shows sp3 hybridization and should have a tetrahedral geometry.

Conclusion

The geometry of a given compound can be predicted using the hybridization of the central atom present.

(c-I)

Expert Solution
Check Mark
Interpretation Introduction

Interpretation: The expected hybridization of the central atom, for the given species, is to be determined.

Concept introduction: The following steps are to be followed to determine the hybridization and the molecular structure of a given compound,

  • The central atom is identified.
  • Its valence electrons are determined.
  • 1e is added to the total number of valence electrons for each monovalent atom present.
  • The total number obtained is divided by 2, to find the number of electron pairs.
  • This further gives us the hybridization of the given compound.

For an atom, present in the structure of a compound, the sum of the number of bonded atoms and the number of lone pairs present on it gives its steric number. The value of the steric number gives us the hybridization of the atom.

To determine: The expected hybridization of the central atom in ClO2.

Answer to Problem 28E

The given compound is sp3 hybridized.

Explanation of Solution

The atomic number of chlorine is 17 and its electronic configuration is,

1s22s22p63s23p5

The valence electron of chlorine is 7

The formula of number of electron pairs is,

X=V+M±C2

Where,

  • X is number of electron pairs.
  • V is valence electrons of central atom.
  • M is number of monovalent atoms.
  • C is charge on compound.

The number of electron pairs is,

X=V+M±C2X=7+12=4

This means that the central atom shows sp3 hybridization and should have a tetrahedral geometry.

Conclusion

The geometry of a given compound can be predicted using the hybridization of the central atom present.

(c-II)

Expert Solution
Check Mark
Interpretation Introduction

Interpretation: The expected hybridization of the central atom, for the given species, is to be determined.

Concept introduction: The following steps are to be followed to determine the hybridization and the molecular structure of a given compound,

  • The central atom is identified.
  • Its valence electrons are determined.
  • 1e is added to the total number of valence electrons for each monovalent atom present.
  • The total number obtained is divided by 2, to find the number of electron pairs.
  • This further gives us the hybridization of the given compound.

For an atom, present in the structure of a compound, the sum of the number of bonded atoms and the number of lone pairs present on it gives its steric number. The value of the steric number gives us the hybridization of the atom.

To determine: The expected hybridization of the central atom in SCl2.

Answer to Problem 28E

The given compound is sp3 hybridized.

Explanation of Solution

The atomic number of chlorine is 17 and its electronic configuration is,

1s22s22p63s23p5

The valence electron of chlorine is 7

The formula of number of electron pairs is,

X=V+M±C2

Where,

  • X is number of electron pairs.
  • V is valence electrons of central atom.
  • M is number of monovalent atoms.
  • C is charge on compound.

The number of electron pairs is,

X=V+M±C2X=6+22=4

This means that the central atom shows sp3 hybridization and should have a tetrahedral geometry.

Conclusion

The geometry of a given compound can be predicted using the hybridization of the central atom present.

(c-III)

Expert Solution
Check Mark
Interpretation Introduction

Interpretation: The expected hybridization of the central atom, for the given species, is to be determined.

Concept introduction: The following steps are to be followed to determine the hybridization and the molecular structure of a given compound,

  • The central atom is identified.
  • Its valence electrons are determined.
  • 1e is added to the total number of valence electrons for each monovalent atom present.
  • The total number obtained is divided by 2, to find the number of electron pairs.
  • This further gives us the hybridization of the given compound.

For an atom, present in the structure of a compound, the sum of the number of bonded atoms and the number of lone pairs present on it gives its steric number. The value of the steric number gives us the hybridization of the atom.

To determine: The expected hybridization of the central atom in PCl2.

Answer to Problem 28E

Answer

The given compound is sp3 hybridized.

Explanation of Solution

The atomic number of chlorine is 17 and its electronic configuration is,

1s22s22p63s23p5

The valence electron of chlorine is 7

The formula of number of electron pairs is,

X=V+M±C2

Where,

  • X is number of electron pairs.
  • V is valence electrons of central atom.
  • M is number of monovalent atoms.
  • C is charge on compound.

The number of electron pairs is,

X=V+M±C2X=5+2+12=4

This means that the central atom shows sp3 hybridization and should have a tetrahedral geometry.

Conclusion

The geometry of a given compound can be predicted using the hybridization of the central atom present.

(d-I)

Expert Solution
Check Mark
Interpretation Introduction

Interpretation: The expected hybridization of the central atom, for the given species, is to be determined.

Concept introduction: The following steps are to be followed to determine the hybridization and the molecular structure of a given compound,

  • The central atom is identified.
  • Its valence electrons are determined.
  • 1e is added to the total number of valence electrons for each monovalent atom present.
  • The total number obtained is divided by 2, to find the number of electron pairs.
  • This further gives us the hybridization of the given compound.

For an atom, present in the structure of a compound, the sum of the number of bonded atoms and the number of lone pairs present on it gives its steric number. The value of the steric number gives us the hybridization of the atom.

To determine: The expected hybridization of the central atom in (O3).

Answer to Problem 28E

The given compound is sp2 hybridized.

Explanation of Solution

The atomic number of oxygen (O) is 8 and its electronic configuration is,

1s22s22p4

The valence electron of oxygen is 6

The formula of number of electron pairs is,

X=V+M±C2

Where,

  • X is number of electron pairs.
  • V is valence electrons of central atom.
  • M is number of monovalent atoms.
  • C is charge on compound.

The number of electron pairs is,

X=V+M±C2X=62=3

This means that the central atom shows sp2 hybridization and should have a triangular planar geometry.

Conclusion

The geometry of a given compound can be predicted using the hybridization of the central atom present.

(d-II)

Expert Solution
Check Mark
Interpretation Introduction

Interpretation: The expected hybridization of the central atom, for the given species, is to be determined.

Concept introduction: The following steps are to be followed to determine the hybridization and the molecular structure of a given compound,

  • The central atom is identified.
  • Its valence electrons are determined.
  • 1e is added to the total number of valence electrons for each monovalent atom present.
  • The total number obtained is divided by 2, to find the number of electron pairs.
  • This further gives us the hybridization of the given compound.

For an atom, present in the structure of a compound, the sum of the number of bonded atoms and the number of lone pairs present on it gives its steric number. The value of the steric number gives us the hybridization of the atom.

To determine: The expected hybridization of the central atom in SO2.

Answer to Problem 28E

The given compound is sp2 hybridized.

Explanation of Solution

The atomic number of sulfur (S) is 16 and its electronic configuration is,

1s22s22p63s23p4

The valence electron of sulfur is 6

The formula of number of electron pairs is,

X=V+M±C2

Where,

  • X is number of electron pairs.
  • V is valence electrons of central atom.
  • M is number of monovalent atoms.
  • C is charge on compound.

The number of electron pairs is,

X=V+M±C2X=62=3

This means that the central atom shows sp2 hybridization and should have a triangular planar geometry.

Conclusion

The geometry of a given compound can be predicted using the hybridization of the central atom present.

(d-III)

Expert Solution
Check Mark
Interpretation Introduction

Interpretation: The expected hybridization of the central atom, for the given species, is to be determined.

Concept introduction: The following steps are to be followed to determine the hybridization and the molecular structure of a given compound,

  • The central atom is identified.
  • Its valence electrons are determined.
  • 1e is added to the total number of valence electrons for each monovalent atom present.
  • The total number obtained is divided by 2, to find the number of electron pairs.
  • This further gives us the hybridization of the given compound.

For an atom, present in the structure of a compound, the sum of the number of bonded atoms and the number of lone pairs present on it gives its steric number. The value of the steric number gives us the hybridization of the atom.

To determine: The expected hybridization of the central atom in SO3.

Answer to Problem 28E

The given compound is sp2 hybridized.

Explanation of Solution

The atomic number of sulfur (S) is 16 and its electronic configuration is,

1s22s22p63s23p4

The valence electron of sulfur is 6.

The formula of number of electron pairs is,

X=V+M±C2

Where,

  • X is number of electron pairs.
  • V is valence electrons of central atom.
  • M is number of monovalent atoms.
  • C is charge on compound.

The number of electron pairs is,

X=V+M±C2X=62=3

This means that the central atom shows sp2 hybridization and should have a triangular planar geometry.

Conclusion

The geometry of a given compound can be predicted using the hybridization of the central atom present.

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Chapter 9 Solutions

Student Solutions Manual for Zumdahl/Zumdahl/DeCoste?s Chemistry, 10th Edition

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    Chemistry
    ISBN:9781133611097
    Author:Steven S. Zumdahl
    Publisher:Cengage Learning
    Text book image
    Chemistry
    Chemistry
    ISBN:9781305957404
    Author:Steven S. Zumdahl, Susan A. Zumdahl, Donald J. DeCoste
    Publisher:Cengage Learning
    Text book image
    Chemistry: An Atoms First Approach
    Chemistry
    ISBN:9781305079243
    Author:Steven S. Zumdahl, Susan A. Zumdahl
    Publisher:Cengage Learning
  • Text book image
    General Chemistry - Standalone book (MindTap Cour...
    Chemistry
    ISBN:9781305580343
    Author:Steven D. Gammon, Ebbing, Darrell Ebbing, Steven D., Darrell; Gammon, Darrell Ebbing; Steven D. Gammon, Darrell D.; Gammon, Ebbing; Steven D. Gammon; Darrell
    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: Principles and Reactions
    Chemistry
    ISBN:9781305079373
    Author:William L. Masterton, Cecile N. Hurley
    Publisher:Cengage Learning
Text book image
Chemistry
Chemistry
ISBN:9781133611097
Author:Steven S. Zumdahl
Publisher:Cengage Learning
Text book image
Chemistry
Chemistry
ISBN:9781305957404
Author:Steven S. Zumdahl, Susan A. Zumdahl, Donald J. DeCoste
Publisher:Cengage Learning
Text book image
Chemistry: An Atoms First Approach
Chemistry
ISBN:9781305079243
Author:Steven S. Zumdahl, Susan A. Zumdahl
Publisher:Cengage Learning
Text book image
General Chemistry - Standalone book (MindTap Cour...
Chemistry
ISBN:9781305580343
Author:Steven D. Gammon, Ebbing, Darrell Ebbing, Steven D., Darrell; Gammon, Darrell Ebbing; Steven D. Gammon, Darrell D.; Gammon, Ebbing; Steven D. Gammon; Darrell
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: Principles and Reactions
Chemistry
ISBN:9781305079373
Author:William L. Masterton, Cecile N. Hurley
Publisher:Cengage Learning
Stoichiometry - Chemistry for Massive Creatures: Crash Course Chemistry #6; Author: Crash Course;https://www.youtube.com/watch?v=UL1jmJaUkaQ;License: Standard YouTube License, CC-BY
Bonding (Ionic, Covalent & Metallic) - GCSE Chemistry; Author: Science Shorts;https://www.youtube.com/watch?v=p9MA6Od-zBA;License: Standard YouTube License, CC-BY
General Chemistry 1A. Lecture 12. Two Theories of Bonding.; Author: UCI Open;https://www.youtube.com/watch?v=dLTlL9Z1bh0;License: CC-BY