The depiction that best illustrates the change in molecular shape around S when SO 3 changes to SO 3 2 − is to be determined. Concept introduction: The following steps are used to determine the molecular shape of the given molecule. Step 1: Write the Lewis structure of the given formula and place the atoms. Step 2: Count all electron groups including bonding and non-bonding pairs around the central atom and use it to assign one of the five electron-group arrangement. Step 3: Write the ideal bond angle related to the electron-group arrangement and the effect of any deviation can be predicted by using VSEPR. Step 4: Count the bonding and non-bonding electron groups and draw the molecular shape accordingly.

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Answer 1

Question

Chapter 10, Problem 10.67P

(a)

Interpretation Introduction

Interpretation:

The depiction that best illustrates the change in molecular shape around S when SO3 changes to SO32− is to be determined.

Concept introduction:

The following steps are used to determine the molecular shape of the given molecule.

Step 1: Write the Lewis structure of the given formula and place the atoms.

Step 2: Count all electron groups including bonding and non-bonding pairs around the central atom and use it to assign one of the five electron-group arrangement.

Step 3: Write the ideal bond angle related to the electron-group arrangement and the effect of any deviation can be predicted by using VSEPR.

Step 4: Count the bonding and non-bonding electron groups and draw the molecular shape accordingly.

(b)

Interpretation Introduction

Interpretation:

Whether the molecular polarity changes in the given reaction or not is to be determined.

Concept introduction:

The dipole moment arises when there is a separation of charges between two ions or atoms involved in the bond. The dipole moment is a vector quantity and its direction towards the most electronegative atom.

The direction of the dipole moment is represented as follows:

The polar and non-polar molecule can be identified on the basis of the net dipole moment. Polar molecules have non zero value of net dipole moment and the nonpolar molecules have zero net dipole moment.

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Answer 2

Question

Chapter 10, Problem 10.67P

(a)

Interpretation Introduction

Interpretation:

The depiction that best illustrates the change in molecular shape around S when SO3 changes to SO32− is to be determined.

Concept introduction:

The following steps are used to determine the molecular shape of the given molecule.

Step 1: Write the Lewis structure of the given formula and place the atoms.

Step 2: Count all electron groups including bonding and non-bonding pairs around the central atom and use it to assign one of the five electron-group arrangement.

Step 3: Write the ideal bond angle related to the electron-group arrangement and the effect of any deviation can be predicted by using VSEPR.

Step 4: Count the bonding and non-bonding electron groups and draw the molecular shape accordingly.

(b)

Interpretation Introduction

Interpretation:

Whether the molecular polarity changes in the given reaction or not is to be determined.

Concept introduction:

The dipole moment arises when there is a separation of charges between two ions or atoms involved in the bond. The dipole moment is a vector quantity and its direction towards the most electronegative atom.

The direction of the dipole moment is represented as follows:

The polar and non-polar molecule can be identified on the basis of the net dipole moment. Polar molecules have non zero value of net dipole moment and the nonpolar molecules have zero net dipole moment.

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Answer 3

Question

Chapter 10, Problem 10.67P

(a)

Interpretation Introduction

Interpretation:

The depiction that best illustrates the change in molecular shape around S when SO3 changes to SO32− is to be determined.

Concept introduction:

The following steps are used to determine the molecular shape of the given molecule.

Step 1: Write the Lewis structure of the given formula and place the atoms.

Step 2: Count all electron groups including bonding and non-bonding pairs around the central atom and use it to assign one of the five electron-group arrangement.

Step 3: Write the ideal bond angle related to the electron-group arrangement and the effect of any deviation can be predicted by using VSEPR.

Step 4: Count the bonding and non-bonding electron groups and draw the molecular shape accordingly.

(b)

Interpretation Introduction

Interpretation:

Whether the molecular polarity changes in the given reaction or not is to be determined.

Concept introduction:

The dipole moment arises when there is a separation of charges between two ions or atoms involved in the bond. The dipole moment is a vector quantity and its direction towards the most electronegative atom.

The direction of the dipole moment is represented as follows:

The polar and non-polar molecule can be identified on the basis of the net dipole moment. Polar molecules have non zero value of net dipole moment and the nonpolar molecules have zero net dipole moment.

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Answer 4

Question

Chapter 10, Problem 10.67P

(a)

Interpretation Introduction

Interpretation:

The depiction that best illustrates the change in molecular shape around S when SO3 changes to SO32− is to be determined.

Concept introduction:

The following steps are used to determine the molecular shape of the given molecule.

Step 1: Write the Lewis structure of the given formula and place the atoms.

Step 2: Count all electron groups including bonding and non-bonding pairs around the central atom and use it to assign one of the five electron-group arrangement.

Step 3: Write the ideal bond angle related to the electron-group arrangement and the effect of any deviation can be predicted by using VSEPR.

Step 4: Count the bonding and non-bonding electron groups and draw the molecular shape accordingly.

(b)

Interpretation Introduction

Interpretation:

Whether the molecular polarity changes in the given reaction or not is to be determined.

Concept introduction:

The dipole moment arises when there is a separation of charges between two ions or atoms involved in the bond. The dipole moment is a vector quantity and its direction towards the most electronegative atom.

The direction of the dipole moment is represented as follows:

The polar and non-polar molecule can be identified on the basis of the net dipole moment. Polar molecules have non zero value of net dipole moment and the nonpolar molecules have zero net dipole moment.

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Answer 5

Chapter 10, Problem 10.67P

(a)

Interpretation Introduction

Interpretation:

The depiction that best illustrates the change in molecular shape around S when SO3 changes to SO32− is to be determined.

Concept introduction:

The following steps are used to determine the molecular shape of the given molecule.

Step 1: Write the Lewis structure of the given formula and place the atoms.

Step 2: Count all electron groups including bonding and non-bonding pairs around the central atom and use it to assign one of the five electron-group arrangement.

Step 3: Write the ideal bond angle related to the electron-group arrangement and the effect of any deviation can be predicted by using VSEPR.

Step 4: Count the bonding and non-bonding electron groups and draw the molecular shape accordingly.

(b)

Interpretation Introduction

Interpretation:

Whether the molecular polarity changes in the given reaction or not is to be determined.

Concept introduction:

The dipole moment arises when there is a separation of charges between two ions or atoms involved in the bond. The dipole moment is a vector quantity and its direction towards the most electronegative atom.

The direction of the dipole moment is represented as follows:

The polar and non-polar molecule can be identified on the basis of the net dipole moment. Polar molecules have non zero value of net dipole moment and the nonpolar molecules have zero net dipole moment.

Answer 6

Chapter 10, Problem 10.67P

(a)

Interpretation Introduction

Interpretation:

The depiction that best illustrates the change in molecular shape around S when SO3 changes to SO32− is to be determined.

Concept introduction:

The following steps are used to determine the molecular shape of the given molecule.

Step 1: Write the Lewis structure of the given formula and place the atoms.

Step 2: Count all electron groups including bonding and non-bonding pairs around the central atom and use it to assign one of the five electron-group arrangement.

Step 3: Write the ideal bond angle related to the electron-group arrangement and the effect of any deviation can be predicted by using VSEPR.

Step 4: Count the bonding and non-bonding electron groups and draw the molecular shape accordingly.

Answer 7

Chapter 10, Problem 10.67P

(a)

Interpretation Introduction

Interpretation:

The depiction that best illustrates the change in molecular shape around S when SO3 changes to SO32− is to be determined.

Concept introduction:

The following steps are used to determine the molecular shape of the given molecule.

Step 1: Write the Lewis structure of the given formula and place the atoms.

Step 2: Count all electron groups including bonding and non-bonding pairs around the central atom and use it to assign one of the five electron-group arrangement.

Step 3: Write the ideal bond angle related to the electron-group arrangement and the effect of any deviation can be predicted by using VSEPR.

Step 4: Count the bonding and non-bonding electron groups and draw the molecular shape accordingly.

Answer 8

(b)

Interpretation Introduction

Interpretation:

Whether the molecular polarity changes in the given reaction or not is to be determined.

Concept introduction:

The dipole moment arises when there is a separation of charges between two ions or atoms involved in the bond. The dipole moment is a vector quantity and its direction towards the most electronegative atom.

The direction of the dipole moment is represented as follows:

The polar and non-polar molecule can be identified on the basis of the net dipole moment. Polar molecules have non zero value of net dipole moment and the nonpolar molecules have zero net dipole moment.

Answer 9

(b)

Interpretation Introduction

Interpretation:

Whether the molecular polarity changes in the given reaction or not is to be determined.

Concept introduction:

The dipole moment arises when there is a separation of charges between two ions or atoms involved in the bond. The dipole moment is a vector quantity and its direction towards the most electronegative atom.

The direction of the dipole moment is represented as follows:

The polar and non-polar molecule can be identified on the basis of the net dipole moment. Polar molecules have non zero value of net dipole moment and the nonpolar molecules have zero net dipole moment.

Answer 10

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Answer 13

Ch. 10.1 - Write a Lewis structure for H2S; ; SOCl2. Ch. 10.1 - Prob. 10.1BFP Ch. 10.1 - Prob. 10.2AFP Ch. 10.1 - Prob. 10.2BFP Ch. 10.1 - Prob. 10.3AFP Ch. 10.1 - Prob. 10.3BFP Ch. 10.1 - Prob. 10.4AFP Ch. 10.1 - Prob. 10.4BFP Ch. 10.1 - Write a Lewis structure with minimal formal...Ch. 10.1 - Prob. 10.5BFP

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