Chemistry with Access Code, Hybrid Edition
Chemistry with Access Code, Hybrid Edition
9th Edition
ISBN: 9781285188492
Author: Steven S. Zumdahl
Publisher: CENGAGE L
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Chapter 20, Problem 68E

(a)

Interpretation Introduction

Interpretation: The Lewis structure, molecular structure (including bond angles) and hybridization of central atom in KrF2,KrF4,XeO2F2 and XeO2F4 is to be stated.

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

  • The central atom is identified.
  • Its valence electrons are determined.
  • The value 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 the hybridization of the given compound.

To determine: The Lewis structure, molecular structure (including bond angles) and hybridization of central atom in KrF2 .

(a)

Expert Solution
Check Mark

Explanation of Solution

The Lewis structure, molecular structure, bond angle and hybridization of central atom in KrF2 is as follows.

The first step in determining the Lewis structure is to determine the number of valence electrons. The atomic number of central atom krypton (Kr) is 36 and its electronic configuration is,

1s22s22p63s23p63d104s24p6

The valence electron of krypton is 8 .

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

1s22s22p5

The valence electron of fluorine is 7 .

The molecule KrF2 is made of two fluorine atoms and single krypton atom; hence, the total number of valence electrons is,

Kr+2F=(8+2×7)e=22e

The formula of number of electron pairs is,

X=V+M±C2

Where,

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

The number of electron pairs is,

X=V+M±C2X=102=5

This means that the central atom shows sp3d hybridization and should have a trigonal bipyramid geometry. But due to presence of repulsive force between lone pairs, the structure becomes linear shaped with the bond angle 180° .

The Lewis structure of KrF2 is,

Chemistry with Access Code, Hybrid Edition, Chapter 20, Problem 68E , additional homework tip  1

Figure 1

(b)

Interpretation Introduction

Interpretation: The Lewis structure, molecular structure (including bond angles) and hybridization of central atom in KrF2,KrF4,XeO2F2 and XeO2F4 is to be stated.

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

  • The central atom is identified.
  • Its valence electrons are determined.
  • The value 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 the hybridization of the given compound.

To determine: The Lewis structure, molecular structure (including bond angles) and hybridization of central atom in KrF4 .

(b)

Expert Solution
Check Mark

Explanation of Solution

The Lewis structure, molecular structure, bond angle and hybridization of central atom in KrF4 is as follows.

The first step in determining the Lewis structure is to determine the number of valence electrons. The atomic number of central atom krypton (Kr) is 36 and its electronic configuration is,

1s22s22p63s23p63d104s24p6

The valence electron of krypton is 8 .

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

1s22s22p5

The valence electron of fluorine is 7 .

The molecule KrF4 is made of four fluorine atoms and single krypton atom; hence, the total number of valence electrons is,

Kr+4F=(8+4×7)e=36e

The formula of number of electron pairs is,

X=V+M±C2

Where,

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

The number of electron pairs is,

X=V+M±C2X=122=6

This means that the central atom shows sp3d2 hybridization and should have a octahedral geometry. But due to presence of repulsive force between lone pairs, the structure becomes square planner shaped with the bond angle 90° .

The Lewis structure of KrF4 is,

Chemistry with Access Code, Hybrid Edition, Chapter 20, Problem 68E , additional homework tip  2

Figure 2

(c)

Interpretation Introduction

Interpretation: The Lewis structure, molecular structure (including bond angles) and hybridization of central atom in KrF2,KrF4,XeO2F2 and XeO2F4 is to be stated.

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

  • The central atom is identified.
  • Its valence electrons are determined.
  • The value 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 the hybridization of the given compound.

To determine: The Lewis structure, molecular structure (including bond angles) and hybridization of central atom in XeO2F2 .

(c)

Expert Solution
Check Mark

Explanation of Solution

The Lewis structure, molecular structure, bond angle and hybridization of central atom in XeO2F2 is as follows.

The first step in determining the Lewis structure is to determine the number of valence electrons. The electronic configuration of central atom xenon (Xe) 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 atomic number of fluorine (F) is 9 and its electronic configuration is,

1s22s22p5

The valence electron of fluorine is 7 .

The molecule XeO2F2 is made of two fluorine atoms, two oxygen atoms and single xenon atom; hence, the total number of valence electrons is,

Xe+2O+2F=(6+6×2+7×2)e=32e

The formula of number of electron pairs is,

X=V+M±C2

Where,

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

The number of electron pairs is,

X=V+M±C2X=102=5

This means that the central atom shows sp3d hybridization and should have a trigonal bipyramid geometry. But due to presence of repulsive force between lone pairs, the structure becomes see-saw shaped with the bond angle 90° and 120° .

The Lewis structure of XeO2F2 is,

Chemistry with Access Code, Hybrid Edition, Chapter 20, Problem 68E , additional homework tip  3

Figure 3

(d)

Interpretation Introduction

Interpretation: The Lewis structure, molecular structure (including bond angles) and hybridization of central atom in KrF2,KrF4,XeO2F2 and XeO2F4 is to be stated.

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

  • The central atom is identified.
  • Its valence electrons are determined.
  • The value 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 the hybridization of the given compound.

To determine: The Lewis structure, molecular structure (including bond angles) and hybridization of central atom in XeO2F4 .

(d)

Expert Solution
Check Mark

Explanation of Solution

The Lewis structure, molecular structure, bond angle and hybridization of central atom in XeO2F4 is as follows.

The first step in determining the Lewis structure is to determine the number of valence electrons. The electronic configuration of central atom xenon (Xe) 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 atomic number of fluorine (F) is 9 and its electronic configuration is,

1s22s22p5

The valence electron of fluorine is 7 .

The molecule XeO2F4 is made of four fluorine atoms, two oxygen atoms and single xenon atom; hence, the total number of valence electrons is,

Xe+2O+4F=(6+6×2+7×4)e=46e

The formula of number of electron pairs is,

X=V+M±C2

Where,

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

The number of electron pairs is,

X=V+M±C2X=122=6

This means that the central atom shows sp3d2 hybridization and should have ocahedral geometry with the bond angle 90° .

The Lewis structure of XeO2F4 is,

Chemistry with Access Code, Hybrid Edition, Chapter 20, Problem 68E , additional homework tip  4

Figure 4

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Chapter 20 Solutions

Chemistry with Access Code, Hybrid Edition

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