The energy required to break all of the bonds in one mole of NH 3 has to be determined. Concept Introduction: The bond dissociation energy or bond energy ( D ) is defined as energy needed to break one mole of bonds in a gaseous species. The equation that describes the bond dissociation for H 2 is as follows: H 2 ( g ) → H ( g ) + H ( g ) Bond energies are always endothermic and have a positive sign. It takes energy to break a bond. The enthalpy of reaction can be determined by the sum of the bond dissociation energies of all the reactants minus the sum of the bond dissociation energies of all products present in chemical reaction . The equation to calculate enthalpy of reaction is as follows: Δ H reaction = [ ∑ ( moles of bond broken × bond energies of bond broken ) − ∑ ( moles of bond formed × bond energies of bond formed ) ] Negative sign in the equation depicts that bonds will form in the products. It is an exothermic process, so the energy charge is the negative of bond energy.

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Answer 1

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Formula Formula Bond dissociation energy (BDE) is the energy required to break a bond, making it an endothermic process. BDE is calculated for a particular bond and therefore consists of fragments such as radicals since it undergoes homolytic bond cleavage. For the homolysis of a X-Y molecule, the energy of bond dissociation is calculated as the difference in the total enthalpy of formation for the reactants and products. X-Y → X + Y BDE = Δ H f X + Δ H f Y – Δ H f X-Y where, ΔHf is the heat of formation.

Chapter 9, Problem 9.85QE

(a)

Interpretation Introduction

Interpretation:

The energy required to break all of the bonds in one mole of NH3 has to be determined.

Concept Introduction:

The bond dissociation energy or bond energy (D) is defined as energy needed to break one mole of bonds in a gaseous species.

The equation that describes the bond dissociation for H2 is as follows:

H2(g)→H(g)+H(g)

Bond energies are always endothermic and have a positive sign. It takes energy to break a bond.

The enthalpy of reaction can be determined by the sum of the bond dissociation energies of all the reactants minus the sum of the bond dissociation energies of all products present in chemical reaction.

The equation to calculate enthalpy of reaction is as follows:

ΔHreaction=[∑(moles of bond broken×bond energies of bond broken)−∑(moles of bond formed×bond energies of bond formed)]

Negative sign in the equation depicts that bonds will form in the products. It is an exothermic process, so the energy charge is the negative of bond energy.

(b)

Interpretation Introduction

Interpretation:

The energy required to break all of the bonds in one mole of CH3OH has to be determined.

Concept Introduction:

Refer to part (a).

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Question 4 For the molecule shown below, (7 marks): A) Sketch the Newman projection for the view looking along the bond from the perspective of the arrow. B) Then, draw the Newman projection for each 60° rotation along the bond until it returns to the starting point. C) Clearly indicate which Newman projection is the one we see in the structure shown below, and clearly indicate which Newman projection is the highest in energy and which is the lowest in energy. H H Me 'H Me Me

Answer 2

Question

Formula Formula Bond dissociation energy (BDE) is the energy required to break a bond, making it an endothermic process. BDE is calculated for a particular bond and therefore consists of fragments such as radicals since it undergoes homolytic bond cleavage. For the homolysis of a X-Y molecule, the energy of bond dissociation is calculated as the difference in the total enthalpy of formation for the reactants and products. X-Y → X + Y BDE = Δ H f X + Δ H f Y – Δ H f X-Y where, ΔHf is the heat of formation.

Chapter 9, Problem 9.85QE

(a)

Interpretation Introduction

Interpretation:

The energy required to break all of the bonds in one mole of NH3 has to be determined.

Concept Introduction:

The bond dissociation energy or bond energy (D) is defined as energy needed to break one mole of bonds in a gaseous species.

The equation that describes the bond dissociation for H2 is as follows:

H2(g)→H(g)+H(g)

Bond energies are always endothermic and have a positive sign. It takes energy to break a bond.

The enthalpy of reaction can be determined by the sum of the bond dissociation energies of all the reactants minus the sum of the bond dissociation energies of all products present in chemical reaction.

The equation to calculate enthalpy of reaction is as follows:

ΔHreaction=[∑(moles of bond broken×bond energies of bond broken)−∑(moles of bond formed×bond energies of bond formed)]

Negative sign in the equation depicts that bonds will form in the products. It is an exothermic process, so the energy charge is the negative of bond energy.

(b)

Interpretation Introduction

Interpretation:

The energy required to break all of the bonds in one mole of CH3OH has to be determined.

Concept Introduction:

Refer to part (a).

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Answer 3

Question

Formula Formula Bond dissociation energy (BDE) is the energy required to break a bond, making it an endothermic process. BDE is calculated for a particular bond and therefore consists of fragments such as radicals since it undergoes homolytic bond cleavage. For the homolysis of a X-Y molecule, the energy of bond dissociation is calculated as the difference in the total enthalpy of formation for the reactants and products. X-Y → X + Y BDE = Δ H f X + Δ H f Y – Δ H f X-Y where, ΔHf is the heat of formation.

Chapter 9, Problem 9.85QE

(a)

Interpretation Introduction

Interpretation:

The energy required to break all of the bonds in one mole of NH3 has to be determined.

Concept Introduction:

The bond dissociation energy or bond energy (D) is defined as energy needed to break one mole of bonds in a gaseous species.

The equation that describes the bond dissociation for H2 is as follows:

H2(g)→H(g)+H(g)

Bond energies are always endothermic and have a positive sign. It takes energy to break a bond.

The enthalpy of reaction can be determined by the sum of the bond dissociation energies of all the reactants minus the sum of the bond dissociation energies of all products present in chemical reaction.

The equation to calculate enthalpy of reaction is as follows:

ΔHreaction=[∑(moles of bond broken×bond energies of bond broken)−∑(moles of bond formed×bond energies of bond formed)]

Negative sign in the equation depicts that bonds will form in the products. It is an exothermic process, so the energy charge is the negative of bond energy.

(b)

Interpretation Introduction

Interpretation:

The energy required to break all of the bonds in one mole of CH3OH has to be determined.

Concept Introduction:

Refer to part (a).

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Answer 4

Question

Formula Formula Bond dissociation energy (BDE) is the energy required to break a bond, making it an endothermic process. BDE is calculated for a particular bond and therefore consists of fragments such as radicals since it undergoes homolytic bond cleavage. For the homolysis of a X-Y molecule, the energy of bond dissociation is calculated as the difference in the total enthalpy of formation for the reactants and products. X-Y → X + Y BDE = Δ H f X + Δ H f Y – Δ H f X-Y where, ΔHf is the heat of formation.

Chapter 9, Problem 9.85QE

(a)

Interpretation Introduction

Interpretation:

The energy required to break all of the bonds in one mole of NH3 has to be determined.

Concept Introduction:

The bond dissociation energy or bond energy (D) is defined as energy needed to break one mole of bonds in a gaseous species.

The equation that describes the bond dissociation for H2 is as follows:

H2(g)→H(g)+H(g)

Bond energies are always endothermic and have a positive sign. It takes energy to break a bond.

The enthalpy of reaction can be determined by the sum of the bond dissociation energies of all the reactants minus the sum of the bond dissociation energies of all products present in chemical reaction.

The equation to calculate enthalpy of reaction is as follows:

ΔHreaction=[∑(moles of bond broken×bond energies of bond broken)−∑(moles of bond formed×bond energies of bond formed)]

Negative sign in the equation depicts that bonds will form in the products. It is an exothermic process, so the energy charge is the negative of bond energy.

(b)

Interpretation Introduction

Interpretation:

The energy required to break all of the bonds in one mole of CH3OH has to be determined.

Concept Introduction:

Refer to part (a).

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Answer 5

Chapter 9, Problem 9.85QE

(a)

Interpretation Introduction

Interpretation:

The energy required to break all of the bonds in one mole of NH3 has to be determined.

Concept Introduction:

The bond dissociation energy or bond energy (D) is defined as energy needed to break one mole of bonds in a gaseous species.

The equation that describes the bond dissociation for H2 is as follows:

H2(g)→H(g)+H(g)

Bond energies are always endothermic and have a positive sign. It takes energy to break a bond.

The enthalpy of reaction can be determined by the sum of the bond dissociation energies of all the reactants minus the sum of the bond dissociation energies of all products present in chemical reaction.

The equation to calculate enthalpy of reaction is as follows:

ΔHreaction=[∑(moles of bond broken×bond energies of bond broken)−∑(moles of bond formed×bond energies of bond formed)]

Negative sign in the equation depicts that bonds will form in the products. It is an exothermic process, so the energy charge is the negative of bond energy.

(b)

Interpretation Introduction

Interpretation:

The energy required to break all of the bonds in one mole of CH3OH has to be determined.

Concept Introduction:

Refer to part (a).

Answer 6

Chapter 9, Problem 9.85QE

(a)

Interpretation Introduction

Interpretation:

The energy required to break all of the bonds in one mole of NH3 has to be determined.

Concept Introduction:

The bond dissociation energy or bond energy (D) is defined as energy needed to break one mole of bonds in a gaseous species.

The equation that describes the bond dissociation for H2 is as follows:

H2(g)→H(g)+H(g)

Bond energies are always endothermic and have a positive sign. It takes energy to break a bond.

The enthalpy of reaction can be determined by the sum of the bond dissociation energies of all the reactants minus the sum of the bond dissociation energies of all products present in chemical reaction.

The equation to calculate enthalpy of reaction is as follows:

ΔHreaction=[∑(moles of bond broken×bond energies of bond broken)−∑(moles of bond formed×bond energies of bond formed)]

Negative sign in the equation depicts that bonds will form in the products. It is an exothermic process, so the energy charge is the negative of bond energy.

Answer 7

Chapter 9, Problem 9.85QE

(a)

Interpretation Introduction

Interpretation:

The energy required to break all of the bonds in one mole of NH3 has to be determined.

Concept Introduction:

The bond dissociation energy or bond energy (D) is defined as energy needed to break one mole of bonds in a gaseous species.

The equation that describes the bond dissociation for H2 is as follows:

H2(g)→H(g)+H(g)

Bond energies are always endothermic and have a positive sign. It takes energy to break a bond.

The enthalpy of reaction can be determined by the sum of the bond dissociation energies of all the reactants minus the sum of the bond dissociation energies of all products present in chemical reaction.

The equation to calculate enthalpy of reaction is as follows:

ΔHreaction=[∑(moles of bond broken×bond energies of bond broken)−∑(moles of bond formed×bond energies of bond formed)]

Negative sign in the equation depicts that bonds will form in the products. It is an exothermic process, so the energy charge is the negative of bond energy.

Answer 8

(b)

Interpretation Introduction

Interpretation:

The energy required to break all of the bonds in one mole of CH3OH has to be determined.

Concept Introduction:

Refer to part (a).

Answer 9

(b)

Interpretation Introduction

Interpretation:

The energy required to break all of the bonds in one mole of CH3OH has to be determined.

Concept Introduction:

Refer to part (a).

Answer 10

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Answer 11

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Answer 12

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Answer 13

Ch. 9 - Prob. 9.1QE Ch. 9 - Prob. 9.2QE Ch. 9 - Prob. 9.3QE Ch. 9 - What main factors control the magnitude of lattice...Ch. 9 - Prob. 9.5QE Ch. 9 - Prob. 9.6QE Ch. 9 - Prob. 9.7QE Ch. 9 - Prob. 9.8QE Ch. 9 - Prob. 9.9QE Ch. 9 - Prob. 9.10QE

Solution Summary: The author explains that the bond dissociation energy or bond energy (D) is defined as energy needed to break one mole of bonds in a gaseous species.

Concept explainers

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Interpretation:

The energy required to break all of the bonds in one mole of CH3OH has to be determined.

Concept Introduction:

Refer to part (a).

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Chapter 9 Solutions

Solution Summary: The author explains that the bond dissociation energy or bond energy (D) is defined as energy needed to break one mole of bonds in a gaseous species.

Concept explainers

Videos

Interpretation: The energy required to break all of the bonds in one mole of CH3OH has to be determined. Concept Introduction: Refer to part (a).

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Chapter 9 Solutions

Interpretation:

The energy required to break all of the bonds in one mole of CH3OH has to be determined.

Concept Introduction:

Refer to part (a).