Identify the fields that are not Maxwellian in free space.

Question

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Answer 1

Question

Chapter 9, Problem 8RQ

To determine

Identify the fields that are not Maxwellian in free space.

Expert Solution & Answer

Answer to Problem 8RQ

The fields that are not Maxwellian in free space are (b) E=100cos(ωt)ax_ and (d) B=0.4sin(104t)az_.

Explanation of Solution

Calculation:

Write the generalized forms of Maxwell’s four Equations.

∇⋅D=ρv (1)

∇⋅B=0 (2)

∇×E=−∂B∂t (3)

∇×H=J+∂D∂t (4)

Rewrite Equation (1) for source-free region.

∇⋅D=0 {∵ρv=0} (5)

Rewrite Equations (3) and (4) for source-free region.

∇×E≠0 (6)

∇×H≠0 (7)

(a) H=cosxcos(106t)ay:

Rewrite Equation (2) for source-free region.

μo∇⋅H=0 {∵B=μoH}

∇⋅H=0 (8)

Find ∇⋅H.

∇⋅H=∇⋅[cosxcos(106t)ay]=(∂∂xax+∂∂yay+∂∂zaz)⋅[cosxcos(106t)ay]=∂∂y[cosxcos(106t)]=0

Find (∇×H).

∇×H=|axayaz∂∂x∂∂y∂∂z0cosxcos(106t)0|={0−∂∂z[cosxcos(106t)]}ax−0ay+∂∂x[cosxcos(106t)]az≠0

As Equations (7) and (8) are satisfied, the field H=cosxcos(106t)ay is a Maxwellian field.

(b) E=100cos(ωt)ax:

Rewrite Equation (5).

εo∇⋅E=0 {∵D=εoE}

∇⋅E=0 (9)

Find ∇⋅E.

∇⋅E=∇⋅[100cos(ωt)ax]=(∂∂xax+∂∂yay+∂∂zaz)⋅[100cos(ωt)ax]=∂∂x[100cos(ωt)]=0

Find (∇×E).

∇×E=|axayaz∂∂x∂∂y∂∂z100cos(ωt)00|=0ax−{0−∂∂z[100cos(ωt)]}ay+{0−∂∂y[100cos(ωt)]}az=0

Equation (9) is satisfied but, Equation (6) is not satisfied. Therefore, the field E=100cos(ωt)ax is not a Maxwellian field.

(c) D=e−10ysin(105t−10y)az:

Find ∇⋅D.

∇⋅D=∇⋅[e−10ysin(105t−10y)az]=(∂∂xax+∂∂yay+∂∂zaz)⋅[e−10ysin(105t−10y)az]=∂∂z[e−10ysin(105t−10y)]=0

Rewrite Equation (6).

∇×E≠01εo∇×D≠0 {∵E=Dεo}

∇×D≠0 (10)

Find (∇×D).

∇×D=|axayaz∂∂x∂∂y∂∂z00e−10ysin(105t−10y)|=∂∂y[e−10ysin(105t−10y)]ax−∂∂x[e−10ysin(105t−10y)]ay+0az=∂∂y[e−10ysin(105t−10y)]ax−0ay+0az≠0

As Equations (5) and (10) are satisfied, the field D=e−10ysin(105t−10y)az is a Maxwellian field.

(d) B=0.4sin(104t)az:

Find ∇⋅B.

∇⋅B=∇⋅[0.4sin(104t)az]=(∂∂xax+∂∂yay+∂∂zaz)⋅[0.4sin(104t)az]=∂∂z[0.4sin(104t)]=0

Rewrite Equation (7).

1μo∇×B≠0 {∵H=Bμo}

∇×B≠0 (11)

Find (∇×B).

∇×B=|axayaz∂∂x∂∂y∂∂z000.4sin(104t)|=∂∂y[0.4sin(104t)]ax−∂∂z[0.4sin(104t)]ay+0az=0

Equation (2) is satisfied but, Equation (11) is not satisfied. Therefore, the field B=0.4sin(104t)az is not a Maxwellian field.

(e) H=10cos(105t−z10)ax:

Find ∇⋅H.

∇⋅H=∇⋅[10cos(105t−z10)ax]=(∂∂xax+∂∂yay+∂∂zaz)⋅[10cos(105t−z10)ax]=∂∂x[10cos(105t−z10)]=0

Find (∇×H).

∇×H=|axayaz∂∂x∂∂y∂∂z10cos(105t−z10)00|=0ax−{0−∂∂z[10cos(105t−z10)]}ay+{0−∂∂y[10cos(105t−z10)]}az=0ax+∂∂z[10cos(105t−z10)]ay+0az≠0

As Equations (7) and (8) are satisfied, the field H=10cos(105t−z10)ax is a Maxwellian field.

(f) E=sinθrcos(ωt−rωμoεo)aθ:

Find ∇⋅E.

∇⋅E=∇⋅[sinθrcos(ωt−rωμoεo)aθ]=(∂∂rar+∂∂θaθ+∂∂ϕaϕ)⋅[sinθrcos(ωt−rωμoεo)aθ]=∂∂θ[sinθrcos(ωt−rωμoεo)]≠0

As Equation (9) is not satisfied, the field E=sinθrcos(ωt−rωμoεo)aθ is not a Maxwellian field.

(g) B=(1−ρ2)sin(ωt)az:

Find ∇⋅B.

∇⋅B=∇⋅[(1−ρ2)sin(ωt)az]=(∂∂ρaρ+∂∂ϕaϕ+∂∂zaz)⋅[(1−ρ2)sin(ωt)az]=∂∂z[(1−ρ2)sin(ωt)]=0

Find (∇×B).

∇×B=|aρaϕaz∂∂ρ1ρ∂∂ϕ∂∂z00(1−ρ2)sin(ωt)|=1ρ∂∂ϕ[(1−ρ2)sin(ωt)]aρ−∂∂ρ[(1−ρ2)sin(ωt)]aϕ+0az=0aρ−∂∂ρ[(1−ρ2)sin(ωt)]aϕ+0az≠0

As Equations (2) and (11) are satisfied, the field B=(1−ρ2)sin(ωt)az is a Maxwellian field.

Conclusion:

Thus, the fields that are not Maxwellian in free space are (b) E=100cos(ωt)ax_ and (d) B=0.4sin(104t)az_.

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Answer 2

Question

Chapter 9, Problem 8RQ

To determine

Identify the fields that are not Maxwellian in free space.

Expert Solution & Answer

Answer to Problem 8RQ

The fields that are not Maxwellian in free space are (b) E=100cos(ωt)ax_ and (d) B=0.4sin(104t)az_.

Explanation of Solution

Calculation:

Write the generalized forms of Maxwell’s four Equations.

∇⋅D=ρv (1)

∇⋅B=0 (2)

∇×E=−∂B∂t (3)

∇×H=J+∂D∂t (4)

Rewrite Equation (1) for source-free region.

∇⋅D=0 {∵ρv=0} (5)

Rewrite Equations (3) and (4) for source-free region.

∇×E≠0 (6)

∇×H≠0 (7)

(a) H=cosxcos(106t)ay:

Rewrite Equation (2) for source-free region.

μo∇⋅H=0 {∵B=μoH}

∇⋅H=0 (8)

Find ∇⋅H.

∇⋅H=∇⋅[cosxcos(106t)ay]=(∂∂xax+∂∂yay+∂∂zaz)⋅[cosxcos(106t)ay]=∂∂y[cosxcos(106t)]=0

Find (∇×H).

∇×H=|axayaz∂∂x∂∂y∂∂z0cosxcos(106t)0|={0−∂∂z[cosxcos(106t)]}ax−0ay+∂∂x[cosxcos(106t)]az≠0

As Equations (7) and (8) are satisfied, the field H=cosxcos(106t)ay is a Maxwellian field.

(b) E=100cos(ωt)ax:

Rewrite Equation (5).

εo∇⋅E=0 {∵D=εoE}

∇⋅E=0 (9)

Find ∇⋅E.

∇⋅E=∇⋅[100cos(ωt)ax]=(∂∂xax+∂∂yay+∂∂zaz)⋅[100cos(ωt)ax]=∂∂x[100cos(ωt)]=0

Find (∇×E).

∇×E=|axayaz∂∂x∂∂y∂∂z100cos(ωt)00|=0ax−{0−∂∂z[100cos(ωt)]}ay+{0−∂∂y[100cos(ωt)]}az=0

Equation (9) is satisfied but, Equation (6) is not satisfied. Therefore, the field E=100cos(ωt)ax is not a Maxwellian field.

(c) D=e−10ysin(105t−10y)az:

Find ∇⋅D.

∇⋅D=∇⋅[e−10ysin(105t−10y)az]=(∂∂xax+∂∂yay+∂∂zaz)⋅[e−10ysin(105t−10y)az]=∂∂z[e−10ysin(105t−10y)]=0

Rewrite Equation (6).

∇×E≠01εo∇×D≠0 {∵E=Dεo}

∇×D≠0 (10)

Find (∇×D).

∇×D=|axayaz∂∂x∂∂y∂∂z00e−10ysin(105t−10y)|=∂∂y[e−10ysin(105t−10y)]ax−∂∂x[e−10ysin(105t−10y)]ay+0az=∂∂y[e−10ysin(105t−10y)]ax−0ay+0az≠0

As Equations (5) and (10) are satisfied, the field D=e−10ysin(105t−10y)az is a Maxwellian field.

(d) B=0.4sin(104t)az:

Find ∇⋅B.

∇⋅B=∇⋅[0.4sin(104t)az]=(∂∂xax+∂∂yay+∂∂zaz)⋅[0.4sin(104t)az]=∂∂z[0.4sin(104t)]=0

Rewrite Equation (7).

1μo∇×B≠0 {∵H=Bμo}

∇×B≠0 (11)

Find (∇×B).

∇×B=|axayaz∂∂x∂∂y∂∂z000.4sin(104t)|=∂∂y[0.4sin(104t)]ax−∂∂z[0.4sin(104t)]ay+0az=0

Equation (2) is satisfied but, Equation (11) is not satisfied. Therefore, the field B=0.4sin(104t)az is not a Maxwellian field.

(e) H=10cos(105t−z10)ax:

Find ∇⋅H.

∇⋅H=∇⋅[10cos(105t−z10)ax]=(∂∂xax+∂∂yay+∂∂zaz)⋅[10cos(105t−z10)ax]=∂∂x[10cos(105t−z10)]=0

Find (∇×H).

∇×H=|axayaz∂∂x∂∂y∂∂z10cos(105t−z10)00|=0ax−{0−∂∂z[10cos(105t−z10)]}ay+{0−∂∂y[10cos(105t−z10)]}az=0ax+∂∂z[10cos(105t−z10)]ay+0az≠0

As Equations (7) and (8) are satisfied, the field H=10cos(105t−z10)ax is a Maxwellian field.

(f) E=sinθrcos(ωt−rωμoεo)aθ:

Find ∇⋅E.

∇⋅E=∇⋅[sinθrcos(ωt−rωμoεo)aθ]=(∂∂rar+∂∂θaθ+∂∂ϕaϕ)⋅[sinθrcos(ωt−rωμoεo)aθ]=∂∂θ[sinθrcos(ωt−rωμoεo)]≠0

As Equation (9) is not satisfied, the field E=sinθrcos(ωt−rωμoεo)aθ is not a Maxwellian field.

(g) B=(1−ρ2)sin(ωt)az:

Find ∇⋅B.

∇⋅B=∇⋅[(1−ρ2)sin(ωt)az]=(∂∂ρaρ+∂∂ϕaϕ+∂∂zaz)⋅[(1−ρ2)sin(ωt)az]=∂∂z[(1−ρ2)sin(ωt)]=0

Find (∇×B).

∇×B=|aρaϕaz∂∂ρ1ρ∂∂ϕ∂∂z00(1−ρ2)sin(ωt)|=1ρ∂∂ϕ[(1−ρ2)sin(ωt)]aρ−∂∂ρ[(1−ρ2)sin(ωt)]aϕ+0az=0aρ−∂∂ρ[(1−ρ2)sin(ωt)]aϕ+0az≠0

As Equations (2) and (11) are satisfied, the field B=(1−ρ2)sin(ωt)az is a Maxwellian field.

Conclusion:

Thus, the fields that are not Maxwellian in free space are (b) E=100cos(ωt)ax_ and (d) B=0.4sin(104t)az_.

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Answer 3

Question

Chapter 9, Problem 8RQ

To determine

Identify the fields that are not Maxwellian in free space.

Expert Solution & Answer

Answer to Problem 8RQ

The fields that are not Maxwellian in free space are (b) E=100cos(ωt)ax_ and (d) B=0.4sin(104t)az_.

Explanation of Solution

Calculation:

Write the generalized forms of Maxwell’s four Equations.

∇⋅D=ρv (1)

∇⋅B=0 (2)

∇×E=−∂B∂t (3)

∇×H=J+∂D∂t (4)

Rewrite Equation (1) for source-free region.

∇⋅D=0 {∵ρv=0} (5)

Rewrite Equations (3) and (4) for source-free region.

∇×E≠0 (6)

∇×H≠0 (7)

(a) H=cosxcos(106t)ay:

Rewrite Equation (2) for source-free region.

μo∇⋅H=0 {∵B=μoH}

∇⋅H=0 (8)

Find ∇⋅H.

∇⋅H=∇⋅[cosxcos(106t)ay]=(∂∂xax+∂∂yay+∂∂zaz)⋅[cosxcos(106t)ay]=∂∂y[cosxcos(106t)]=0

Find (∇×H).

∇×H=|axayaz∂∂x∂∂y∂∂z0cosxcos(106t)0|={0−∂∂z[cosxcos(106t)]}ax−0ay+∂∂x[cosxcos(106t)]az≠0

As Equations (7) and (8) are satisfied, the field H=cosxcos(106t)ay is a Maxwellian field.

(b) E=100cos(ωt)ax:

Rewrite Equation (5).

εo∇⋅E=0 {∵D=εoE}

∇⋅E=0 (9)

Find ∇⋅E.

∇⋅E=∇⋅[100cos(ωt)ax]=(∂∂xax+∂∂yay+∂∂zaz)⋅[100cos(ωt)ax]=∂∂x[100cos(ωt)]=0

Find (∇×E).

∇×E=|axayaz∂∂x∂∂y∂∂z100cos(ωt)00|=0ax−{0−∂∂z[100cos(ωt)]}ay+{0−∂∂y[100cos(ωt)]}az=0

Equation (9) is satisfied but, Equation (6) is not satisfied. Therefore, the field E=100cos(ωt)ax is not a Maxwellian field.

(c) D=e−10ysin(105t−10y)az:

Find ∇⋅D.

∇⋅D=∇⋅[e−10ysin(105t−10y)az]=(∂∂xax+∂∂yay+∂∂zaz)⋅[e−10ysin(105t−10y)az]=∂∂z[e−10ysin(105t−10y)]=0

Rewrite Equation (6).

∇×E≠01εo∇×D≠0 {∵E=Dεo}

∇×D≠0 (10)

Find (∇×D).

∇×D=|axayaz∂∂x∂∂y∂∂z00e−10ysin(105t−10y)|=∂∂y[e−10ysin(105t−10y)]ax−∂∂x[e−10ysin(105t−10y)]ay+0az=∂∂y[e−10ysin(105t−10y)]ax−0ay+0az≠0

As Equations (5) and (10) are satisfied, the field D=e−10ysin(105t−10y)az is a Maxwellian field.

(d) B=0.4sin(104t)az:

Find ∇⋅B.

∇⋅B=∇⋅[0.4sin(104t)az]=(∂∂xax+∂∂yay+∂∂zaz)⋅[0.4sin(104t)az]=∂∂z[0.4sin(104t)]=0

Rewrite Equation (7).

1μo∇×B≠0 {∵H=Bμo}

∇×B≠0 (11)

Find (∇×B).

∇×B=|axayaz∂∂x∂∂y∂∂z000.4sin(104t)|=∂∂y[0.4sin(104t)]ax−∂∂z[0.4sin(104t)]ay+0az=0

Equation (2) is satisfied but, Equation (11) is not satisfied. Therefore, the field B=0.4sin(104t)az is not a Maxwellian field.

(e) H=10cos(105t−z10)ax:

Find ∇⋅H.

∇⋅H=∇⋅[10cos(105t−z10)ax]=(∂∂xax+∂∂yay+∂∂zaz)⋅[10cos(105t−z10)ax]=∂∂x[10cos(105t−z10)]=0

Find (∇×H).

∇×H=|axayaz∂∂x∂∂y∂∂z10cos(105t−z10)00|=0ax−{0−∂∂z[10cos(105t−z10)]}ay+{0−∂∂y[10cos(105t−z10)]}az=0ax+∂∂z[10cos(105t−z10)]ay+0az≠0

As Equations (7) and (8) are satisfied, the field H=10cos(105t−z10)ax is a Maxwellian field.

(f) E=sinθrcos(ωt−rωμoεo)aθ:

Find ∇⋅E.

∇⋅E=∇⋅[sinθrcos(ωt−rωμoεo)aθ]=(∂∂rar+∂∂θaθ+∂∂ϕaϕ)⋅[sinθrcos(ωt−rωμoεo)aθ]=∂∂θ[sinθrcos(ωt−rωμoεo)]≠0

As Equation (9) is not satisfied, the field E=sinθrcos(ωt−rωμoεo)aθ is not a Maxwellian field.

(g) B=(1−ρ2)sin(ωt)az:

Find ∇⋅B.

∇⋅B=∇⋅[(1−ρ2)sin(ωt)az]=(∂∂ρaρ+∂∂ϕaϕ+∂∂zaz)⋅[(1−ρ2)sin(ωt)az]=∂∂z[(1−ρ2)sin(ωt)]=0

Find (∇×B).

∇×B=|aρaϕaz∂∂ρ1ρ∂∂ϕ∂∂z00(1−ρ2)sin(ωt)|=1ρ∂∂ϕ[(1−ρ2)sin(ωt)]aρ−∂∂ρ[(1−ρ2)sin(ωt)]aϕ+0az=0aρ−∂∂ρ[(1−ρ2)sin(ωt)]aϕ+0az≠0

As Equations (2) and (11) are satisfied, the field B=(1−ρ2)sin(ωt)az is a Maxwellian field.

Conclusion:

Thus, the fields that are not Maxwellian in free space are (b) E=100cos(ωt)ax_ and (d) B=0.4sin(104t)az_.

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Answer 4

Question

Chapter 9, Problem 8RQ

To determine

Identify the fields that are not Maxwellian in free space.

Expert Solution & Answer

Answer to Problem 8RQ

The fields that are not Maxwellian in free space are (b) E=100cos(ωt)ax_ and (d) B=0.4sin(104t)az_.

Explanation of Solution

Calculation:

Write the generalized forms of Maxwell’s four Equations.

∇⋅D=ρv (1)

∇⋅B=0 (2)

∇×E=−∂B∂t (3)

∇×H=J+∂D∂t (4)

Rewrite Equation (1) for source-free region.

∇⋅D=0 {∵ρv=0} (5)

Rewrite Equations (3) and (4) for source-free region.

∇×E≠0 (6)

∇×H≠0 (7)

(a) H=cosxcos(106t)ay:

Rewrite Equation (2) for source-free region.

μo∇⋅H=0 {∵B=μoH}

∇⋅H=0 (8)

Find ∇⋅H.

∇⋅H=∇⋅[cosxcos(106t)ay]=(∂∂xax+∂∂yay+∂∂zaz)⋅[cosxcos(106t)ay]=∂∂y[cosxcos(106t)]=0

Find (∇×H).

∇×H=|axayaz∂∂x∂∂y∂∂z0cosxcos(106t)0|={0−∂∂z[cosxcos(106t)]}ax−0ay+∂∂x[cosxcos(106t)]az≠0

As Equations (7) and (8) are satisfied, the field H=cosxcos(106t)ay is a Maxwellian field.

(b) E=100cos(ωt)ax:

Rewrite Equation (5).

εo∇⋅E=0 {∵D=εoE}

∇⋅E=0 (9)

Find ∇⋅E.

∇⋅E=∇⋅[100cos(ωt)ax]=(∂∂xax+∂∂yay+∂∂zaz)⋅[100cos(ωt)ax]=∂∂x[100cos(ωt)]=0

Find (∇×E).

∇×E=|axayaz∂∂x∂∂y∂∂z100cos(ωt)00|=0ax−{0−∂∂z[100cos(ωt)]}ay+{0−∂∂y[100cos(ωt)]}az=0

Equation (9) is satisfied but, Equation (6) is not satisfied. Therefore, the field E=100cos(ωt)ax is not a Maxwellian field.

(c) D=e−10ysin(105t−10y)az:

Find ∇⋅D.

∇⋅D=∇⋅[e−10ysin(105t−10y)az]=(∂∂xax+∂∂yay+∂∂zaz)⋅[e−10ysin(105t−10y)az]=∂∂z[e−10ysin(105t−10y)]=0

Rewrite Equation (6).

∇×E≠01εo∇×D≠0 {∵E=Dεo}

∇×D≠0 (10)

Find (∇×D).

∇×D=|axayaz∂∂x∂∂y∂∂z00e−10ysin(105t−10y)|=∂∂y[e−10ysin(105t−10y)]ax−∂∂x[e−10ysin(105t−10y)]ay+0az=∂∂y[e−10ysin(105t−10y)]ax−0ay+0az≠0

As Equations (5) and (10) are satisfied, the field D=e−10ysin(105t−10y)az is a Maxwellian field.

(d) B=0.4sin(104t)az:

Find ∇⋅B.

∇⋅B=∇⋅[0.4sin(104t)az]=(∂∂xax+∂∂yay+∂∂zaz)⋅[0.4sin(104t)az]=∂∂z[0.4sin(104t)]=0

Rewrite Equation (7).

1μo∇×B≠0 {∵H=Bμo}

∇×B≠0 (11)

Find (∇×B).

∇×B=|axayaz∂∂x∂∂y∂∂z000.4sin(104t)|=∂∂y[0.4sin(104t)]ax−∂∂z[0.4sin(104t)]ay+0az=0

Equation (2) is satisfied but, Equation (11) is not satisfied. Therefore, the field B=0.4sin(104t)az is not a Maxwellian field.

(e) H=10cos(105t−z10)ax:

Find ∇⋅H.

∇⋅H=∇⋅[10cos(105t−z10)ax]=(∂∂xax+∂∂yay+∂∂zaz)⋅[10cos(105t−z10)ax]=∂∂x[10cos(105t−z10)]=0

Find (∇×H).

∇×H=|axayaz∂∂x∂∂y∂∂z10cos(105t−z10)00|=0ax−{0−∂∂z[10cos(105t−z10)]}ay+{0−∂∂y[10cos(105t−z10)]}az=0ax+∂∂z[10cos(105t−z10)]ay+0az≠0

As Equations (7) and (8) are satisfied, the field H=10cos(105t−z10)ax is a Maxwellian field.

(f) E=sinθrcos(ωt−rωμoεo)aθ:

Find ∇⋅E.

∇⋅E=∇⋅[sinθrcos(ωt−rωμoεo)aθ]=(∂∂rar+∂∂θaθ+∂∂ϕaϕ)⋅[sinθrcos(ωt−rωμoεo)aθ]=∂∂θ[sinθrcos(ωt−rωμoεo)]≠0

As Equation (9) is not satisfied, the field E=sinθrcos(ωt−rωμoεo)aθ is not a Maxwellian field.

(g) B=(1−ρ2)sin(ωt)az:

Find ∇⋅B.

∇⋅B=∇⋅[(1−ρ2)sin(ωt)az]=(∂∂ρaρ+∂∂ϕaϕ+∂∂zaz)⋅[(1−ρ2)sin(ωt)az]=∂∂z[(1−ρ2)sin(ωt)]=0

Find (∇×B).

∇×B=|aρaϕaz∂∂ρ1ρ∂∂ϕ∂∂z00(1−ρ2)sin(ωt)|=1ρ∂∂ϕ[(1−ρ2)sin(ωt)]aρ−∂∂ρ[(1−ρ2)sin(ωt)]aϕ+0az=0aρ−∂∂ρ[(1−ρ2)sin(ωt)]aϕ+0az≠0

As Equations (2) and (11) are satisfied, the field B=(1−ρ2)sin(ωt)az is a Maxwellian field.

Conclusion:

Thus, the fields that are not Maxwellian in free space are (b) E=100cos(ωt)ax_ and (d) B=0.4sin(104t)az_.

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Answer 5

Chapter 9, Problem 8RQ

To determine

Identify the fields that are not Maxwellian in free space.

Expert Solution & Answer

Answer to Problem 8RQ

The fields that are not Maxwellian in free space are (b) E=100cos(ωt)ax_ and (d) B=0.4sin(104t)az_.

Explanation of Solution

Calculation:

Write the generalized forms of Maxwell’s four Equations.

∇⋅D=ρv (1)

∇⋅B=0 (2)

∇×E=−∂B∂t (3)

∇×H=J+∂D∂t (4)

Rewrite Equation (1) for source-free region.

∇⋅D=0 {∵ρv=0} (5)

Rewrite Equations (3) and (4) for source-free region.

∇×E≠0 (6)

∇×H≠0 (7)

(a) H=cosxcos(106t)ay:

Rewrite Equation (2) for source-free region.

μo∇⋅H=0 {∵B=μoH}

∇⋅H=0 (8)

Find ∇⋅H.

∇⋅H=∇⋅[cosxcos(106t)ay]=(∂∂xax+∂∂yay+∂∂zaz)⋅[cosxcos(106t)ay]=∂∂y[cosxcos(106t)]=0

Find (∇×H).

∇×H=|axayaz∂∂x∂∂y∂∂z0cosxcos(106t)0|={0−∂∂z[cosxcos(106t)]}ax−0ay+∂∂x[cosxcos(106t)]az≠0

As Equations (7) and (8) are satisfied, the field H=cosxcos(106t)ay is a Maxwellian field.

(b) E=100cos(ωt)ax:

Rewrite Equation (5).

εo∇⋅E=0 {∵D=εoE}

∇⋅E=0 (9)

Find ∇⋅E.

∇⋅E=∇⋅[100cos(ωt)ax]=(∂∂xax+∂∂yay+∂∂zaz)⋅[100cos(ωt)ax]=∂∂x[100cos(ωt)]=0

Find (∇×E).

∇×E=|axayaz∂∂x∂∂y∂∂z100cos(ωt)00|=0ax−{0−∂∂z[100cos(ωt)]}ay+{0−∂∂y[100cos(ωt)]}az=0

Equation (9) is satisfied but, Equation (6) is not satisfied. Therefore, the field E=100cos(ωt)ax is not a Maxwellian field.

(c) D=e−10ysin(105t−10y)az:

Find ∇⋅D.

∇⋅D=∇⋅[e−10ysin(105t−10y)az]=(∂∂xax+∂∂yay+∂∂zaz)⋅[e−10ysin(105t−10y)az]=∂∂z[e−10ysin(105t−10y)]=0

Rewrite Equation (6).

∇×E≠01εo∇×D≠0 {∵E=Dεo}

∇×D≠0 (10)

Find (∇×D).

∇×D=|axayaz∂∂x∂∂y∂∂z00e−10ysin(105t−10y)|=∂∂y[e−10ysin(105t−10y)]ax−∂∂x[e−10ysin(105t−10y)]ay+0az=∂∂y[e−10ysin(105t−10y)]ax−0ay+0az≠0

As Equations (5) and (10) are satisfied, the field D=e−10ysin(105t−10y)az is a Maxwellian field.

(d) B=0.4sin(104t)az:

Find ∇⋅B.

∇⋅B=∇⋅[0.4sin(104t)az]=(∂∂xax+∂∂yay+∂∂zaz)⋅[0.4sin(104t)az]=∂∂z[0.4sin(104t)]=0

Rewrite Equation (7).

1μo∇×B≠0 {∵H=Bμo}

∇×B≠0 (11)

Find (∇×B).

∇×B=|axayaz∂∂x∂∂y∂∂z000.4sin(104t)|=∂∂y[0.4sin(104t)]ax−∂∂z[0.4sin(104t)]ay+0az=0

Equation (2) is satisfied but, Equation (11) is not satisfied. Therefore, the field B=0.4sin(104t)az is not a Maxwellian field.

(e) H=10cos(105t−z10)ax:

Find ∇⋅H.

∇⋅H=∇⋅[10cos(105t−z10)ax]=(∂∂xax+∂∂yay+∂∂zaz)⋅[10cos(105t−z10)ax]=∂∂x[10cos(105t−z10)]=0

Find (∇×H).

∇×H=|axayaz∂∂x∂∂y∂∂z10cos(105t−z10)00|=0ax−{0−∂∂z[10cos(105t−z10)]}ay+{0−∂∂y[10cos(105t−z10)]}az=0ax+∂∂z[10cos(105t−z10)]ay+0az≠0

As Equations (7) and (8) are satisfied, the field H=10cos(105t−z10)ax is a Maxwellian field.

(f) E=sinθrcos(ωt−rωμoεo)aθ:

Find ∇⋅E.

∇⋅E=∇⋅[sinθrcos(ωt−rωμoεo)aθ]=(∂∂rar+∂∂θaθ+∂∂ϕaϕ)⋅[sinθrcos(ωt−rωμoεo)aθ]=∂∂θ[sinθrcos(ωt−rωμoεo)]≠0

As Equation (9) is not satisfied, the field E=sinθrcos(ωt−rωμoεo)aθ is not a Maxwellian field.

(g) B=(1−ρ2)sin(ωt)az:

Find ∇⋅B.

∇⋅B=∇⋅[(1−ρ2)sin(ωt)az]=(∂∂ρaρ+∂∂ϕaϕ+∂∂zaz)⋅[(1−ρ2)sin(ωt)az]=∂∂z[(1−ρ2)sin(ωt)]=0

Find (∇×B).

∇×B=|aρaϕaz∂∂ρ1ρ∂∂ϕ∂∂z00(1−ρ2)sin(ωt)|=1ρ∂∂ϕ[(1−ρ2)sin(ωt)]aρ−∂∂ρ[(1−ρ2)sin(ωt)]aϕ+0az=0aρ−∂∂ρ[(1−ρ2)sin(ωt)]aϕ+0az≠0

As Equations (2) and (11) are satisfied, the field B=(1−ρ2)sin(ωt)az is a Maxwellian field.

Conclusion:

Thus, the fields that are not Maxwellian in free space are (b) E=100cos(ωt)ax_ and (d) B=0.4sin(104t)az_.

Answer 6

Chapter 9, Problem 8RQ

To determine

Identify the fields that are not Maxwellian in free space.

Expert Solution & Answer

Answer to Problem 8RQ

The fields that are not Maxwellian in free space are (b) E=100cos(ωt)ax_ and (d) B=0.4sin(104t)az_.

Explanation of Solution

Calculation:

Write the generalized forms of Maxwell’s four Equations.

∇⋅D=ρv (1)

∇⋅B=0 (2)

∇×E=−∂B∂t (3)

∇×H=J+∂D∂t (4)

Rewrite Equation (1) for source-free region.

∇⋅D=0 {∵ρv=0} (5)

Rewrite Equations (3) and (4) for source-free region.

∇×E≠0 (6)

∇×H≠0 (7)

(a) H=cosxcos(106t)ay:

Rewrite Equation (2) for source-free region.

μo∇⋅H=0 {∵B=μoH}

∇⋅H=0 (8)

Find ∇⋅H.

∇⋅H=∇⋅[cosxcos(106t)ay]=(∂∂xax+∂∂yay+∂∂zaz)⋅[cosxcos(106t)ay]=∂∂y[cosxcos(106t)]=0

Find (∇×H).

∇×H=|axayaz∂∂x∂∂y∂∂z0cosxcos(106t)0|={0−∂∂z[cosxcos(106t)]}ax−0ay+∂∂x[cosxcos(106t)]az≠0

As Equations (7) and (8) are satisfied, the field H=cosxcos(106t)ay is a Maxwellian field.

(b) E=100cos(ωt)ax:

Rewrite Equation (5).

εo∇⋅E=0 {∵D=εoE}

∇⋅E=0 (9)

Find ∇⋅E.

∇⋅E=∇⋅[100cos(ωt)ax]=(∂∂xax+∂∂yay+∂∂zaz)⋅[100cos(ωt)ax]=∂∂x[100cos(ωt)]=0

Find (∇×E).

∇×E=|axayaz∂∂x∂∂y∂∂z100cos(ωt)00|=0ax−{0−∂∂z[100cos(ωt)]}ay+{0−∂∂y[100cos(ωt)]}az=0

Equation (9) is satisfied but, Equation (6) is not satisfied. Therefore, the field E=100cos(ωt)ax is not a Maxwellian field.

(c) D=e−10ysin(105t−10y)az:

Find ∇⋅D.

∇⋅D=∇⋅[e−10ysin(105t−10y)az]=(∂∂xax+∂∂yay+∂∂zaz)⋅[e−10ysin(105t−10y)az]=∂∂z[e−10ysin(105t−10y)]=0

Rewrite Equation (6).

∇×E≠01εo∇×D≠0 {∵E=Dεo}

∇×D≠0 (10)

Find (∇×D).

∇×D=|axayaz∂∂x∂∂y∂∂z00e−10ysin(105t−10y)|=∂∂y[e−10ysin(105t−10y)]ax−∂∂x[e−10ysin(105t−10y)]ay+0az=∂∂y[e−10ysin(105t−10y)]ax−0ay+0az≠0

As Equations (5) and (10) are satisfied, the field D=e−10ysin(105t−10y)az is a Maxwellian field.

(d) B=0.4sin(104t)az:

Find ∇⋅B.

∇⋅B=∇⋅[0.4sin(104t)az]=(∂∂xax+∂∂yay+∂∂zaz)⋅[0.4sin(104t)az]=∂∂z[0.4sin(104t)]=0

Rewrite Equation (7).

1μo∇×B≠0 {∵H=Bμo}

∇×B≠0 (11)

Find (∇×B).

∇×B=|axayaz∂∂x∂∂y∂∂z000.4sin(104t)|=∂∂y[0.4sin(104t)]ax−∂∂z[0.4sin(104t)]ay+0az=0

Equation (2) is satisfied but, Equation (11) is not satisfied. Therefore, the field B=0.4sin(104t)az is not a Maxwellian field.

(e) H=10cos(105t−z10)ax:

Find ∇⋅H.

∇⋅H=∇⋅[10cos(105t−z10)ax]=(∂∂xax+∂∂yay+∂∂zaz)⋅[10cos(105t−z10)ax]=∂∂x[10cos(105t−z10)]=0

Find (∇×H).

∇×H=|axayaz∂∂x∂∂y∂∂z10cos(105t−z10)00|=0ax−{0−∂∂z[10cos(105t−z10)]}ay+{0−∂∂y[10cos(105t−z10)]}az=0ax+∂∂z[10cos(105t−z10)]ay+0az≠0

As Equations (7) and (8) are satisfied, the field H=10cos(105t−z10)ax is a Maxwellian field.

(f) E=sinθrcos(ωt−rωμoεo)aθ:

Find ∇⋅E.

∇⋅E=∇⋅[sinθrcos(ωt−rωμoεo)aθ]=(∂∂rar+∂∂θaθ+∂∂ϕaϕ)⋅[sinθrcos(ωt−rωμoεo)aθ]=∂∂θ[sinθrcos(ωt−rωμoεo)]≠0

As Equation (9) is not satisfied, the field E=sinθrcos(ωt−rωμoεo)aθ is not a Maxwellian field.

(g) B=(1−ρ2)sin(ωt)az:

Find ∇⋅B.

∇⋅B=∇⋅[(1−ρ2)sin(ωt)az]=(∂∂ρaρ+∂∂ϕaϕ+∂∂zaz)⋅[(1−ρ2)sin(ωt)az]=∂∂z[(1−ρ2)sin(ωt)]=0

Find (∇×B).

∇×B=|aρaϕaz∂∂ρ1ρ∂∂ϕ∂∂z00(1−ρ2)sin(ωt)|=1ρ∂∂ϕ[(1−ρ2)sin(ωt)]aρ−∂∂ρ[(1−ρ2)sin(ωt)]aϕ+0az=0aρ−∂∂ρ[(1−ρ2)sin(ωt)]aϕ+0az≠0

As Equations (2) and (11) are satisfied, the field B=(1−ρ2)sin(ωt)az is a Maxwellian field.

Conclusion:

Thus, the fields that are not Maxwellian in free space are (b) E=100cos(ωt)ax_ and (d) B=0.4sin(104t)az_.

Answer 7

Chapter 9, Problem 8RQ

To determine

Identify the fields that are not Maxwellian in free space.

Answer 8

Expert Solution & Answer

Answer to Problem 8RQ

The fields that are not Maxwellian in free space are (b) E=100cos(ωt)ax_ and (d) B=0.4sin(104t)az_.

Answer 9

Expert Solution & Answer

Answer 10

Expert Solution & Answer

Answer 11

Explanation of Solution

Calculation:

Write the generalized forms of Maxwell’s four Equations.

∇⋅D=ρv (1)

∇⋅B=0 (2)

∇×E=−∂B∂t (3)

∇×H=J+∂D∂t (4)

Rewrite Equation (1) for source-free region.

∇⋅D=0 {∵ρv=0} (5)

Rewrite Equations (3) and (4) for source-free region.

∇×E≠0 (6)

∇×H≠0 (7)

(a) H=cosxcos(106t)ay:

Rewrite Equation (2) for source-free region.

μo∇⋅H=0 {∵B=μoH}

∇⋅H=0 (8)

Find ∇⋅H.

∇⋅H=∇⋅[cosxcos(106t)ay]=(∂∂xax+∂∂yay+∂∂zaz)⋅[cosxcos(106t)ay]=∂∂y[cosxcos(106t)]=0

Find (∇×H).

∇×H=|axayaz∂∂x∂∂y∂∂z0cosxcos(106t)0|={0−∂∂z[cosxcos(106t)]}ax−0ay+∂∂x[cosxcos(106t)]az≠0

As Equations (7) and (8) are satisfied, the field H=cosxcos(106t)ay is a Maxwellian field.

(b) E=100cos(ωt)ax:

Rewrite Equation (5).

εo∇⋅E=0 {∵D=εoE}

∇⋅E=0 (9)

Find ∇⋅E.

∇⋅E=∇⋅[100cos(ωt)ax]=(∂∂xax+∂∂yay+∂∂zaz)⋅[100cos(ωt)ax]=∂∂x[100cos(ωt)]=0

Find (∇×E).

∇×E=|axayaz∂∂x∂∂y∂∂z100cos(ωt)00|=0ax−{0−∂∂z[100cos(ωt)]}ay+{0−∂∂y[100cos(ωt)]}az=0

Equation (9) is satisfied but, Equation (6) is not satisfied. Therefore, the field E=100cos(ωt)ax is not a Maxwellian field.

(c) D=e−10ysin(105t−10y)az:

Find ∇⋅D.

∇⋅D=∇⋅[e−10ysin(105t−10y)az]=(∂∂xax+∂∂yay+∂∂zaz)⋅[e−10ysin(105t−10y)az]=∂∂z[e−10ysin(105t−10y)]=0

Rewrite Equation (6).

∇×E≠01εo∇×D≠0 {∵E=Dεo}

∇×D≠0 (10)

Find (∇×D).

∇×D=|axayaz∂∂x∂∂y∂∂z00e−10ysin(105t−10y)|=∂∂y[e−10ysin(105t−10y)]ax−∂∂x[e−10ysin(105t−10y)]ay+0az=∂∂y[e−10ysin(105t−10y)]ax−0ay+0az≠0

As Equations (5) and (10) are satisfied, the field D=e−10ysin(105t−10y)az is a Maxwellian field.

(d) B=0.4sin(104t)az:

Find ∇⋅B.

∇⋅B=∇⋅[0.4sin(104t)az]=(∂∂xax+∂∂yay+∂∂zaz)⋅[0.4sin(104t)az]=∂∂z[0.4sin(104t)]=0

Rewrite Equation (7).

1μo∇×B≠0 {∵H=Bμo}

∇×B≠0 (11)

Find (∇×B).

∇×B=|axayaz∂∂x∂∂y∂∂z000.4sin(104t)|=∂∂y[0.4sin(104t)]ax−∂∂z[0.4sin(104t)]ay+0az=0

Equation (2) is satisfied but, Equation (11) is not satisfied. Therefore, the field B=0.4sin(104t)az is not a Maxwellian field.

(e) H=10cos(105t−z10)ax:

Find ∇⋅H.

∇⋅H=∇⋅[10cos(105t−z10)ax]=(∂∂xax+∂∂yay+∂∂zaz)⋅[10cos(105t−z10)ax]=∂∂x[10cos(105t−z10)]=0

Find (∇×H).

∇×H=|axayaz∂∂x∂∂y∂∂z10cos(105t−z10)00|=0ax−{0−∂∂z[10cos(105t−z10)]}ay+{0−∂∂y[10cos(105t−z10)]}az=0ax+∂∂z[10cos(105t−z10)]ay+0az≠0

As Equations (7) and (8) are satisfied, the field H=10cos(105t−z10)ax is a Maxwellian field.

(f) E=sinθrcos(ωt−rωμoεo)aθ:

Find ∇⋅E.

∇⋅E=∇⋅[sinθrcos(ωt−rωμoεo)aθ]=(∂∂rar+∂∂θaθ+∂∂ϕaϕ)⋅[sinθrcos(ωt−rωμoεo)aθ]=∂∂θ[sinθrcos(ωt−rωμoεo)]≠0

As Equation (9) is not satisfied, the field E=sinθrcos(ωt−rωμoεo)aθ is not a Maxwellian field.

(g) B=(1−ρ2)sin(ωt)az:

Find ∇⋅B.

∇⋅B=∇⋅[(1−ρ2)sin(ωt)az]=(∂∂ρaρ+∂∂ϕaϕ+∂∂zaz)⋅[(1−ρ2)sin(ωt)az]=∂∂z[(1−ρ2)sin(ωt)]=0

Find (∇×B).

∇×B=|aρaϕaz∂∂ρ1ρ∂∂ϕ∂∂z00(1−ρ2)sin(ωt)|=1ρ∂∂ϕ[(1−ρ2)sin(ωt)]aρ−∂∂ρ[(1−ρ2)sin(ωt)]aϕ+0az=0aρ−∂∂ρ[(1−ρ2)sin(ωt)]aϕ+0az≠0

As Equations (2) and (11) are satisfied, the field B=(1−ρ2)sin(ωt)az is a Maxwellian field.

Conclusion:

Thus, the fields that are not Maxwellian in free space are (b) E=100cos(ωt)ax_ and (d) B=0.4sin(104t)az_.

Answer 12

Ch. 9.3 - Prob. 1PE Ch. 9.3 - Prob. 2PE Ch. 9.3 - Prob. 3PE Ch. 9.4 - Prob. 4PE Ch. 9.7 - Prob. 5PE Ch. 9.7 - Prob. 6PE Ch. 9.7 - Prob. 7PE Ch. 9.7 - Prob. 8PE Ch. 9 - Prob. 1RQ Ch. 9 - Prob. 2RQ

Identify the fields that are not Maxwellian in free space.

Identify the fields that are not Maxwellian in free space.

Answer to Problem 8RQ

Explanation of Solution

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Chapter 9 Solutions