Chemistry: An Atoms First Approach
Chemistry: An Atoms First Approach
2nd Edition
ISBN: 9781305079243
Author: Steven S. Zumdahl, Susan A. Zumdahl
Publisher: Cengage Learning
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Chapter 4, Problem 24E

(a-i)

Interpretation Introduction

Interpretation: The molecular structure of given compound is to be predicted from exercise 82 and 84 in chapter 3.

Concept introduction: Molecular structure is a three-dimensional shape of a molecule.

Bond angle is the angle between atoms of molecule.

To determine: The molecular structure of POCl3 (including bond angles).

(a-i)

Expert Solution
Check Mark

Explanation of Solution

The steps are to be followed to determine the molecular structure is:

  • Identify the central atom.
  • Count its valence electrons.
  • Add or subtract electrons for charge.
  • Draw the Lewis structure.
  • Divide the total number of electrons by 2 to find the number of electron pairs.
  • Use this number to predict the shape.

The central atom in POCl3 is phosphorous (P). The atomic number of phosphorous is 15 and its electronic configuration is,

1s22s22p63s23p3

The valence electron of phosphorous is 5

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

1s22s22p63s23p5

The valence electron of chlorine is 7

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

1s22s22p4

The valence electron of oxygen is 6

The molecule POCl3 is made of three chlorine atoms and one phosphorus and oxygen atom; hence, the total number of valence electrons is,

P+O+3Cl=5+6+3×7=32

The Lewis structure of POCl3 is

Chemistry: An Atoms First Approach, Chapter 4, Problem 24E , additional homework tip  1

Figure 1

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

The shape of compound is tetrahedral and bond angle is 109.50

(a-ii)

Interpretation Introduction

Interpretation: The molecular structure of given compound is to be predicted from exercise 82 and 84 in chapter 3.

Concept introduction: Molecular structure is a three-dimensional shape of a molecule.

Bond angle is the angle between atoms of molecule.

To determine: The molecular structure of SO42 (including bond angles).

(a-ii)

Expert Solution
Check Mark

Explanation of Solution

The steps are to be followed to determine the molecular structure is:

  • Identify the central atom.
  • Count its valence electrons.
  • Add or subtract electrons for charge.
  • Draw the Lewis structure.
  • Divide the total number of electrons by 2 to find the number of electron pairs.
  • Use this number to predict the shape.

The central atom in SO42 is sulfur (S). The atomic number of sulfur is 16 and its electronic configuration is,

1s22s22p63s23p4

The valence electron of sulfur is 6

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

1s22s22p4

The valence electron of oxygen is 6

The molecule SO42 is made of four oxygen atoms and one sulfur atom; hence, the total number of valence electrons is,

S+4O+2e=6+4×6+2=32

The Lewis structure of SO42 is

Chemistry: An Atoms First Approach, Chapter 4, Problem 24E , additional homework tip  2

Figure 2

The formula of number of electron pairs is

X=V+M±C2

The number of electron pairs is

X=V+M±C2X=6+22=4

The shape of compound is tetrahedral and bond angle is 109.50

(a-iii)

Interpretation Introduction

Interpretation: The molecular structure of given compound is to be predicted from exercise 82 and 84 in chapter 3.

Concept introduction: Molecular structure is a three-dimensional shape of a molecule.

Bond angle is the angle between atoms of molecule.

To determine: The molecular structure of XeO4 (including bond angles).

(a-iii)

Expert Solution
Check Mark

Explanation of Solution

The steps are to be followed to determine the molecular structure is:

  • Identify the central atom.
  • Count its valence electrons.
  • Add or subtract electrons for charge.
  • Draw the Lewis structure.
  • Divide the total number of electrons by 2 to find the number of electron pairs.
  • Use this number to predict the shape.

The central atom in XeO4 is xenon (Xe). The atomic number of xenon is 54 and its electronic configuration is,

1s22s22p63s23p63d104s24p64d105s25p6

The valence electron of xenon is 8

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

1s22s22p4

The valence electron of oxygen is 6

The molecule XeO4 is made of four oxygen atoms and xenon atom; hence, the total number of valence electrons is,

Xe+4O+=8+4×6+2=32

The Lewis structure of XeO4 is

Chemistry: An Atoms First Approach, Chapter 4, Problem 24E , additional homework tip  3

Figure 3

The formula of number of electron pairs is

X=V+M±C2

The number of electron pairs is

X=V+M±C2X=82=4

The shape of compound is tetrahedral and bond angle is 109.50

(a-iv)

Interpretation Introduction

Interpretation: The molecular structure of given compound is to be predicted from exercise 82 and 84 in chapter 3.

Concept introduction: Molecular structure is a three-dimensional shape of a molecule.

Bond angle is the angle between atoms of molecule.

To determine: The molecular structure of PO43 (including bond angles).

(a-iv)

Expert Solution
Check Mark

Explanation of Solution

The steps are to be followed to determine the molecular structure is:

  • Identify the central atom.
  • Count its valence electrons.
  • Add or subtract electrons for charge.
  • Draw the Lewis structure.
  • Divide the total number of electrons by 2 to find the number of electron pairs.
  • Use this number to predict the shape.

The central atom in PO43 is phosphorous (P). The atomic number of phosphorous is 15 and its electronic configuration is,

1s22s22p63s23p3

The valence electron of phosphorous is 5

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

1s22s22p4

The valence electron of oxygen is 6

The molecule PO43 is made of four oxygen atoms and phosphorous atom; hence, the total number of valence electrons is,

P+4O+3e=5+4×6+3=32

The Lewis structure of PO43 is

Chemistry: An Atoms First Approach, Chapter 4, Problem 24E , additional homework tip  4

Figure 4

The formula of number of electron pairs is

X=V+M±C2

The number of electron pairs is

X=V+M±C2X=5+32=4

The shape of compound is tetrahedral and bond angle is 109.50

(a-v)

Interpretation Introduction

Interpretation: The molecular structure of given compound is to be predicted from exercise 82 and 84 in chapter 3.

Concept introduction: Molecular structure is a three-dimensional shape of a molecule.

Bond angle is the angle between atoms of molecule.

To determine: The molecular structure of ClO4 (including bond angles).

(a-v)

Expert Solution
Check Mark

Explanation of Solution

The steps are to be followed to determine the molecular structure is:

  • Identify the central atom.
  • Count its valence electrons.
  • Add or subtract electrons for charge.
  • Draw the Lewis structure.
  • Divide the total number of electrons by 2 to find the number of electron pairs.
  • Use this number to predict the shape.

The central atom in ClO4 is chlorine (Cl). The atomic number of chlorine is 17 and its electronic configuration is,

1s22s22p63s23p5

The valence electron of chlorine is 7

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

1s22s22p4

The valence electron of oxygen is 6

The molecule ClO4 is made of four oxygen atoms and chlorine atom; hence, the total number of valence electrons is,

Cl+4O+e=7+4×6+1=32

The Lewis structure of ClO4 is

Chemistry: An Atoms First Approach, Chapter 4, Problem 24E , additional homework tip  5

Figure 5

The formula of number of electron pairs is

X=V+M±C2

The number of electron pairs is

X=V+M±C2X=7+12=4

The shape of compound is tetrahedral and bond angle is 109.50

(b-i)

Interpretation Introduction

Interpretation: The molecular structure of given compound is to be predicted from exercise 82 and 84 in chapter 3.

Concept introduction: Molecular structure is a three-dimensional shape of a molecule.

Bond angle is the angle between atoms of molecule.

To determine: The molecular structure of NF3 (including bond angles).

(b-i)

Expert Solution
Check Mark

Explanation of Solution

The steps are to be followed to determine the molecular structure is:

  • Identify the central atom.
  • Count its valence electrons.
  • Add or subtract electrons for charge.
  • Draw the Lewis structure.
  • Divide the total number of electrons by 2 to find the number of electron pairs.
  • Use this number to predict the shape.

The central atom in NF3 is nitrogen (N). The atomic number of nitrogen is 7 and its electronic configuration is,

1s22s22p3

The valence electron of nitrogen is 5

The atomic number of fluorine is 9 and its electronic configuration is,

1s22s22p5

The valence electron of fluorine is 7

The molecule NF3 is made of three fluorine atoms and one nitrogen atom; hence, the total number of valence electrons is,

3F+1N=3×7+5=26

The Lewis structure of NF3 is

Chemistry: An Atoms First Approach, Chapter 4, Problem 24E , additional homework tip  6

Figure 6

The formula of number of electron pairs is

X=V+M±C2

The number of electron pairs is

X=V+M±C2X=5+32=4

The shape of compound is trigonal planner

In NF3 compound nitrogen contains one lone pair and each oxygen atom contains three lone pairs The repulsion between the lone pairs and bond pairs causes the rearrangement of shape of NF3.

Hence, the structure becomes trigonal pyramidal and bond angle is <109.50.

(b-ii)

Interpretation Introduction

Interpretation: The molecular structure of given compound is to be predicted from exercise 82 and 84 in chapter 3.

Concept introduction: Molecular structure is a three-dimensional shape of a molecule.

Bond angle is the angle between atoms of molecule.

To determine: The molecular structure of SO32 (including bond angles).

(b-ii)

Expert Solution
Check Mark

Explanation of Solution

The steps are to be followed to determine the molecular structure is:

  • Identify the central atom.
  • Count its valence electrons.
  • Add or subtract electrons for charge.
  • Draw the Lewis structure.
  • Divide the total number of electrons by 2 to find the number of electron pairs.
  • Use this number to predict the shape.

The central atom in SO32 is sulfur (S). The atomic number of sulfur is 16 and its electronic configuration is,

1s22s22p63s23p4

The valence electron of sulfur is 6

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

1s22s22p4

The valence electron of oxygen is 6

The molecule SO32 is made of three oxygen atoms and one sulfur atom. Also oxygen atom contains two negative charge; hence, the total number of valence electrons is,

S+3O+2e=6+3×6+2=26

The Lewis structure of SO32 is

Chemistry: An Atoms First Approach, Chapter 4, Problem 24E , additional homework tip  7

Figure 7

The formula of number of electron pairs is

X=V+M±C2

The number of electron pairs is

X=V+M±C2X=6+22=4

The shape of compound is trigonal planner

In SO32 compound sulfur contains one lone pair and each oxygen atom contains three lone pairs The repulsion between the lone pairs and bond pairs causes the rearrangement of shape of SO32.

Hence, the structure becomes trigonal pyramidal and bond angle is <109.50.

(c-iii)

Interpretation Introduction

Interpretation: The molecular structure of given compound is to be predicted from exercise 82 and 84 in chapter 3.

Concept introduction: Molecular structure is a three-dimensional shape of a molecule.

Bond angle is the angle between atoms of molecule.

To determine: The molecular structure of PO33 (including bond angles).

(c-iii)

Expert Solution
Check Mark

Explanation of Solution

The steps are to be followed to determine the molecular structure is:

  • Identify the central atom.
  • Count its valence electrons.
  • Add or subtract electrons for charge.
  • Draw the Lewis structure.
  • Divide the total number of electrons by 2 to find the number of electron pairs.
  • Use this number to predict the shape.

The central atom in PO33 is phosphorous (P). The atomic number of phosphorous is 15 and its electronic configuration is,

1s22s22p63s23p3

The valence electron of phosphorous is 5

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

1s22s22p4

The valence electron of oxygen is 6

The molecule PO33 is made of three oxygen atoms and phosphorous atom. Also oxygen atoms contain three negative charges; hence, the total number of valence electrons is,

P+3O+3e=5+3×6+3=26

The Lewis structure of PO33 is

Chemistry: An Atoms First Approach, Chapter 4, Problem 24E , additional homework tip  8

Figure 8

The shape of compound is trigonal planner

In PO33 compound phosphorous contains one lone pair whereas each oxygen atom contains three lone pairs The repulsion between the lone pairs and bond pairs causes the rearrangement of shape of PO33.

Hence, the structure becomes trigonal pyramidal and bond angle is <109.50.

(d-iv)

Interpretation Introduction

Interpretation: The molecular structure of given compound is to be predicted from exercise 82 and 84 in chapter 3.

Concept introduction: Molecular structure is a three-dimensional shape of a molecule.

Bond angle is the angle between atoms of molecule.

To determine: The molecular structure of ClO3 (including bond angles).

(d-iv)

Expert Solution
Check Mark

Explanation of Solution

The steps are to be followed to determine the molecular structure is:

  • Identify the central atom.
  • Count its valence electrons.
  • Add or subtract electrons for charge.
  • Draw the Lewis structure.
  • Divide the total number of electrons by 2 to find the number of electron pairs.
  • Use this number to predict the shape.

The central atom in ClO3 is chlorine (Cl). . The atomic number of chlorine is 17 and its electronic configuration is,

1s22s22p63s23p5

The valence electron of chlorine is 7

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

1s22s22p4

The valence electron of oxygen is 6

The molecule ClO3 is made of three oxygen atoms and chlorine atom. Also oxygen atoms contain three negative charges; hence, the total number of valence electrons is,

Cl+3O+e=7+3×6+1=26

The Lewis structure of ClO3 is

Chemistry: An Atoms First Approach, Chapter 4, Problem 24E , additional homework tip  9

Figure 9

The shape of compound is trigonal planner

In ClO3 compound chlorine contains one lone pair whereas each oxygen atom contains three lone pairs The repulsion between the lone pairs and bond pairs causes the rearrangement of shape of ClO3.

Hence, the structure becomes trigonal pyramidal and bond angle is <109.50.

(c)

(c-i)

Interpretation Introduction

Interpretation: The molecular structure of given compound is to be predicted from exercise 82 and 84 in chapter 3.

Concept introduction: Molecular structure is a three-dimensional shape of a molecule.

Bond angle is the angle between atoms of molecule.

To determine: The molecular structure of ClO2 (including bond angles).

(c)

(c-i)

Expert Solution
Check Mark

Explanation of Solution

The central atom in ClO2 is chlorine (Cl). The atomic number of chlorine is 17 and its electronic configuration is,

1s22s22p63s23p5

The valence electron of chlorine is 7

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

1s22s22p4

The valence electron of oxygen is 6

The molecule ClO2 is made of two oxygen atoms and chlorine atom. Also oxygen atoms contain one negative charges; hence, the total number of valence electrons is,

Cl+2O+e=7+2×6+1=20

The Lewis structure of ClO2 is

Chemistry: An Atoms First Approach, Chapter 4, Problem 24E , additional homework tip  10

Figure 10

The shape of compound is linear.

In ClO3 compound chlorine contains two lone pair whereas each oxygen atom contains three lone pairs The repulsion between the lone pairs and bond pairs causes the rearrangement of shape of ClO3.

Hence, the structure becomes bent shaped and bond angle is <109.50.

(c-ii)

Interpretation Introduction

Interpretation: The molecular structure of given compound is to be predicted from exercise 82 and 84 in chapter 3.

Concept introduction: Molecular structure is a three-dimensional shape of a molecule.

Bond angle is the angle between atoms of molecule.

To determine: The molecular structure of SCl2 (including bond angles).

(c-ii)

Expert Solution
Check Mark

Explanation of Solution

The central atom in SCl2 is sulfur (S). The atomic number of chlorine is 17 and its electronic configuration is,

1s22s22p63s23p5

The valence electron of chlorine is 7

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

1s22s22p63s23p4

The valence electron of sulfur is 6

The molecule SCl2 is made of two chlorine atoms and sulfur atom; hence, the total number of valence electrons is,

2Cl+S=2×7+6=20

The Lewis structure of SCl2 is

Chemistry: An Atoms First Approach, Chapter 4, Problem 24E , additional homework tip  11

Figure 11

The shape of compound is linear.

In SCl2 compound sulfur contains two lone pair whereas each chlorine atom contains three lone pairs The repulsion between the lone pairs and bond pairs causes the rearrangement of shape of SCl2.

Hence, the structure becomes bent shaped and bond angle is <109.50.

(d-iii)

Interpretation Introduction

Interpretation: The molecular structure of given compound is to be predicted from exercise 82 and 84 in chapter 3.

Concept introduction: Molecular structure is a three-dimensional shape of a molecule.

Bond angle is the angle between atoms of molecule.

To determine: The molecular structure of PCl2 (including bond angles).

(d-iii)

Expert Solution
Check Mark

Explanation of Solution

Explanation:

The central atom in PCl2 is sulfur (S). The atomic number of chlorine is 17 and its electronic configuration is,

1s22s22p63s23p5

The valence electron of chlorine is 7

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

1s22s22p63s23p3

The valence electron of sulfur is 5

The molecule PCl2 is made of two chlorine atoms and phosphorous atom. Also chlorine atom contains single negative charge; hence, the total number of valence electrons is,

2Cl+P+e=2×7+5+1=20

The Lewis structure of PCl2 is

Chemistry: An Atoms First Approach, Chapter 4, Problem 24E , additional homework tip  12

Figure 12

The shape of compound is linear.

In PCl2 compound phosphorous contains two lone pair whereas each chlorine atom contains three lone pairs The repulsion between the lone pairs and bond pairs causes the rearrangement of shape of PCl2.

Hence, the structure becomes bent shaped and bond angle is <109.50.

(d-i)

Interpretation Introduction

Interpretation: The molecular structure of given compound is to be predicted from exercise 82 and 84 in chapter 3.

Concept introduction: Molecular structure is a three-dimensional shape of a molecule.

Bond angle is the angle between atoms of molecule.

To determine: The molecular structure of (O3) (including bond angles).

(d-i)

Expert Solution
Check Mark

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 molecule (O3) is made of three oxygen atoms.; hence, the total number of valence electrons is,

3O=3×6=18

The Lewis structure of (O3) is

Chemistry: An Atoms First Approach, Chapter 4, Problem 24E , additional homework tip  13

Figure 13

Hence, the shape of compound is V-shaped and bond angle is 1200

(ii)

To determine: The molecular structure of SO3 (including bond angles).

Explanation:

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

1s22s22p63s23p4

The valence electron of sulfur is 6

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

1s22s22p4

The valence electron of oxygen is 6

The molecule SO2 is made of two oxygen atoms and one sulfur atom; hence, the total number of valence electrons is,

S+2O=6+2×6=18

The Lewis structure of SO2 is

Chemistry: An Atoms First Approach, Chapter 4, Problem 24E , additional homework tip  14

Figure 14

Hence, the shape of compound is V-shaped and bond angle is 1200

(d-ii)

Interpretation Introduction

Interpretation: The molecular structure of given compound is to be predicted from exercise 82 and 84 in chapter 3.

Concept introduction: Molecular structure is a three-dimensional shape of a molecule.

Bond angle is the angle between atoms of molecule.

To determine: The molecular structure of SO2 (including bond angles).

(d-ii)

Expert Solution
Check Mark

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

1s22s22p4

The valence electron of oxygen is 6

The molecule SO2 is made of two oxygen atoms and one sulfur atom; hence, the total number of valence electrons is,

S+2O=6+2×6=18

The Lewis structure of SO2 is

Chemistry: An Atoms First Approach, Chapter 4, Problem 24E , additional homework tip  15

Figure 14

Hence, the shape of compound is V-shaped and bond angle is 1200

(d-iii)

Interpretation Introduction

Interpretation: The molecular structure of given compound is to be predicted from exercise 82 and 84 in chapter 3.

Concept introduction: Molecular structure is a three-dimensional shape of a molecule.

Bond angle is the angle between atoms of molecule.

To determine: The molecular structure of SO3 (including bond angles).

(d-iii)

Expert Solution
Check Mark

Explanation of Solution

Explanation:

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

1s22s22p63s23p4

The valence electron of sulfur is 6

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

1s22s22p4

The valence electron of oxygen is 6

The molecule SO3 is made of two oxygen atoms and one sulfur atom; hence, the total number of valence electrons is,

S+2O=6+2×6=18

The Lewis structure of SO3 is

Chemistry: An Atoms First Approach, Chapter 4, Problem 24E , additional homework tip  16

Figure 15

Hence, the shape of compound is trigonal planner and bond angle is 1200.

Conclusion

The molecular structure describes the relative position of atoms in a molecule

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Author:Klaus Theopold, Richard H Langley, Paul Flowers, William R. Robinson, Mark Blaser
Publisher:OpenStax
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Chemistry for Engineering Students
Chemistry
ISBN:9781337398909
Author:Lawrence S. Brown, Tom Holme
Publisher:Cengage Learning
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Introductory Chemistry: A Foundation
Chemistry
ISBN:9781337399425
Author:Steven S. Zumdahl, Donald J. DeCoste
Publisher:Cengage Learning
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Chemistry
Chemistry
ISBN:9781133611097
Author:Steven S. Zumdahl
Publisher:Cengage Learning
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Chemistry
Chemistry
ISBN:9781305957404
Author:Steven S. Zumdahl, Susan A. Zumdahl, Donald J. DeCoste
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