From the given set of species the species that gets dissociated by absorbing energy that equals wavelength in visible region should be determined. Concept introduction: Visible Range: The electromagnetic radiation which range is about 390 nm to 700 nm is considered as visible since the human eye can able to detect this range. UV Range: The electromagnetic radiation which range is about 100 nm to 400nm is regarded as ultraviolet region and they are shorter than the visible region. Bond Enthalpy: The energy required in order to form the bond between the two atoms is called bond enthalpy. Bond Dissociation Energy : The minimum energy required to break a bond between two atoms present in the molecule is called bond dissociation energy. Energy: The energy is conversed property since it can neither be created nor be destroyed but can be transformed. The energy of the photon is obtained by using the following relation E = hν h → Planck's constant = 6 .63 × 10 -34 J .s ν → frequency of the photon Wavelength: The distance between the two continuous maximum displacements present in wave or the two continuous minimum displacements present in a wave exhibited by the photons is called wavelength. The wavelength of the photon is inversely proportional to its frequency. The relationship between them is given by the following formula, (wavelength)λ = (velocity of light)c (frequency)ν Frequency: It denotes the number of waves passes in given amount of time.

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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 21.2, Problem 1PPB

Interpretation Introduction

Interpretation: From the given set of species the species that gets dissociated by absorbing energy that equals wavelength in visible region should be determined.

Concept introduction:

Visible Range: The electromagnetic radiation which range is about 390 nm to 700 nm is considered as visible since the human eye can able to detect this range.

UV Range: The electromagnetic radiation which range is about 100 nm to 400nm is regarded as ultraviolet region and they are shorter than the visible region.

Bond Enthalpy: The energy required in order to form the bond between the two atoms is called bond enthalpy.

Bond Dissociation Energy: The minimum energy required to break a bond between two atoms present in the molecule is called bond dissociation energy.

Energy: The energy is conversed property since it can neither be created nor be destroyed but can be transformed. The energy of the photon is obtained by using the following relation

E = hνh→Planck's constant = 6.63×10-34J.sν→frequency of the photon

Wavelength: The distance between the two continuous maximum displacements present in wave or the two continuous minimum displacements present in a wave exhibited by the photons is called wavelength. The wavelength of the photon is inversely proportional to its frequency. The relationship between them is given by the following formula,

(wavelength)λ = (velocity of light)c(frequency)ν

Frequency: It denotes the number of waves passes in given amount of time.

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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 21.2, Problem 1PPB

Interpretation Introduction

Interpretation: From the given set of species the species that gets dissociated by absorbing energy that equals wavelength in visible region should be determined.

Concept introduction:

Visible Range: The electromagnetic radiation which range is about 390 nm to 700 nm is considered as visible since the human eye can able to detect this range.

UV Range: The electromagnetic radiation which range is about 100 nm to 400nm is regarded as ultraviolet region and they are shorter than the visible region.

Bond Enthalpy: The energy required in order to form the bond between the two atoms is called bond enthalpy.

Bond Dissociation Energy: The minimum energy required to break a bond between two atoms present in the molecule is called bond dissociation energy.

Energy: The energy is conversed property since it can neither be created nor be destroyed but can be transformed. The energy of the photon is obtained by using the following relation

E = hνh→Planck's constant = 6.63×10-34J.sν→frequency of the photon

Wavelength: The distance between the two continuous maximum displacements present in wave or the two continuous minimum displacements present in a wave exhibited by the photons is called wavelength. The wavelength of the photon is inversely proportional to its frequency. The relationship between them is given by the following formula,

(wavelength)λ = (velocity of light)c(frequency)ν

Frequency: It denotes the number of waves passes in given amount of time.

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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 21.2, Problem 1PPB

Interpretation Introduction

Interpretation: From the given set of species the species that gets dissociated by absorbing energy that equals wavelength in visible region should be determined.

Concept introduction:

Visible Range: The electromagnetic radiation which range is about 390 nm to 700 nm is considered as visible since the human eye can able to detect this range.

UV Range: The electromagnetic radiation which range is about 100 nm to 400nm is regarded as ultraviolet region and they are shorter than the visible region.

Bond Enthalpy: The energy required in order to form the bond between the two atoms is called bond enthalpy.

Bond Dissociation Energy: The minimum energy required to break a bond between two atoms present in the molecule is called bond dissociation energy.

Energy: The energy is conversed property since it can neither be created nor be destroyed but can be transformed. The energy of the photon is obtained by using the following relation

E = hνh→Planck's constant = 6.63×10-34J.sν→frequency of the photon

Wavelength: The distance between the two continuous maximum displacements present in wave or the two continuous minimum displacements present in a wave exhibited by the photons is called wavelength. The wavelength of the photon is inversely proportional to its frequency. The relationship between them is given by the following formula,

(wavelength)λ = (velocity of light)c(frequency)ν

Frequency: It denotes the number of waves passes in given amount of time.

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Check out a sample textbook solution

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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 21.2, Problem 1PPB

Interpretation Introduction