Find whether the given field D is electrostatic or magnetostatic field in free space.

Question

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Answer 1

Question

Chapter 7, Problem 41P

(a)

To determine

Find whether the given field D is electrostatic or magnetostatic field in free space.

(a)

Expert Solution

Answer to Problem 41P

The vector D is possibly a magnetostatic field.

Explanation of Solution

Calculation:

Given field is,

D=y2zax+2(x+1)yzax−(x+1)z2az

Generally, the vector is a magnetostatic field if its dot product is zero and the vector is an electrostatic field if its cross product is zero. That is,

For magnetostatic field, ∇⋅(vector)=0

For electrostatic field, ∇×(vector)=0

Substitute y2zax+2(x+1)yzax−(x+1)z2az for D to find ∇⋅D.

∇⋅D=∂∂xDx+∂∂yDy+∂∂zDz=∂∂x(y2z)+∂∂y(2(x+1))+∂∂z(−(x+1))=0+0+0=0

Substitute y2zax+2(x+1)yzax−(x+1)z2az for D to find ∇×D.

∇×D=|axayaz∂∂x∂∂y∂∂zDxDyDz|=|axayaz∂∂x∂∂y∂∂zy2z2(x+1)yz−(x+1)z2|=[(∂∂y(−(x+1)z2)−∂∂z(2(x+1)yz))ax−(∂∂x(−(x+1)z2)−∂∂z(y2z))ay+(∂∂x(2(x+1)yz)−∂∂y(y2z))az]=[((0)−2(x+1)y(1))ax−(−((1)z2+0)−y2(1))ay+((2(1)yz+0)−(2y)z)az]

Simplify the above equation.

∇×D=(−2(x+1)y)ax−(−z2−y2)ay+(2yz−2yz)az=(−2(x+1)y)ax+(z2+y2)ay+(0)az=−2(x+1)yax+(z2+y2)ay≠0

Therefore, for the field D,

∇⋅D=0∇×D≠0

Conclusion:

Thus, the vector D is possibly a magnetostatic field.

(b)

To determine

Find whether the given field E is electrostatic or magnetostatic field in free space.

(b)

Expert Solution

Answer to Problem 41P

The vector E is possibly a magnetostatic field.

Explanation of Solution

Calculation:

Given field is,

E=(z+1)ρcosϕaρ+sinϕρaz

Substitute (z+1)ρcosϕaρ+sinϕρaz for E to find ∇⋅E.

∇⋅E=1ρ∂∂ρ(ρEρ)+1ρ∂∂ϕEϕ+∂∂zEz=1ρ∂∂ρ(ρ((z+1)ρcosϕ))+1ρ∂∂ϕ(0)+∂∂z(sinϕρ)=1ρ∂∂ρ((z+1)cosϕ)+0+0=0

Substitute (z+1)ρcosϕaρ+sinϕρaz for E to find ∇×E.

∇×E=1ρ|aρρaϕaz∂∂ρ∂∂ϕ∂∂z(z+1)ρcosϕρ(0)sinϕρ|=1ρ|aρρaϕaz∂∂ρ∂∂ϕ∂∂z(z+1)ρcosϕ0sinϕρ|=1ρ[(∂∂ϕ(sinϕρ)−∂∂z(0))aρ−(∂∂ρ(sinϕρ)−∂∂z((z+1)ρcosϕ))ρaϕ+(∂∂ρ(0)−∂∂ϕ((z+1)ρcosϕ))az]=1ρ[∂∂ϕ(sinϕρ)aρ−(∂∂ρ(sinϕρ)−∂∂z((z+1)ρcosϕ))ρaϕ−∂∂ϕ((z+1)ρcosϕ)az]

Simplify the above equation.

∇×E=1ρ[cosϕρaρ−ρ(sinϕ(−1ρ2)−(cosϕρ)(1+0))aϕ−(z+1)ρ(−sinϕ)az]=1ρ[cosϕρaρ−ρ(−sinϕρ2−(cosϕρ))aϕ+(z+1)sinϕρaz]=cosϕρ2aρ−(−sinϕρ2−(cosϕρ))aϕ+(z+1)sinϕρ2az≠0

Therefore, for the field E,

∇⋅E=0∇×E≠0

Conclusion:

Thus, the vector E is possibly a magnetostatic field.

(c)

To determine

Find whether the given field F is electrostatic or magnetostatic field in free space.

(c)

Expert Solution

Answer to Problem 41P

The vector F is neither electrostatic nor magnetostatic field.

Explanation of Solution

Calculation:

Given field is,

F=1r2(2cosθar+sinθaθ)=2r2cosθar+1r2sinθaθ

Substitute 2r2cosθar+1r2sinθaθ for F to find ∇⋅F.

∇⋅F=1r2∂∂r(r2Fr)+1rsinθ∂∂θ(sinθFθ)+1rsinθ∂∂ϕ(Fϕ)=1r2∂∂r(r2(2r2cosθ))+1rsinθ∂∂θ(sinθ(1r2sinθ))+1rsinθ∂∂ϕ(0)=1r2∂∂r(2cosθ)+1rsinθ∂∂θ(1r2sin2θ)+0=1r2(0)+1r3sinθ(2sinθcosθ)

Simplify the above equation.

∇⋅F=0+1r3(2cosθ)=2cosθr3≠0

Substitute 2r2cosθar+1r2sinθaθ for F to find ∇×F.

∇×F=1r2sinθ|arraθrsinθaϕ∂∂r∂∂θ∂∂ϕ2r2cosθr(1r2sinθ)0|=1r2sinθ|arraθrsinθaϕ∂∂r∂∂θ∂∂ϕ2r2cosθ1rsinθ0|=1r2sinθ[(∂∂θ(0)−∂∂ϕ(1rsinθ))ar−(∂∂r(0)−∂∂ϕ(2r2cosθ))raθ+(∂∂r(1rsinθ)−∂∂θ(2r2cosθ))rsinθaϕ]=1r2sinθ[(0−(0))ar−(0−(0))raθ+(sinθ(−1r2)−(2r2)(−sinθ))rsinθaϕ]

Simplify the above equation.

∇×F=1r2sinθ[0+0+rsinθ(−1r2sinθ+2r2sinθ)aϕ]=rsinθr2sinθ(−1r2sinθ+2r2sinθ)aϕ=1r3(sinθ)aϕ≠0

Therefore, for the field F,

∇⋅F≠0∇×F≠0

Conclusion:

Thus, the vector F is neither electrostatic nor magnetostatic field.

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Answer 2

Question

Chapter 7, Problem 41P

(a)

To determine

Find whether the given field D is electrostatic or magnetostatic field in free space.

(a)

Expert Solution

Answer to Problem 41P

The vector D is possibly a magnetostatic field.

Explanation of Solution

Calculation:

Given field is,

D=y2zax+2(x+1)yzax−(x+1)z2az

Generally, the vector is a magnetostatic field if its dot product is zero and the vector is an electrostatic field if its cross product is zero. That is,

For magnetostatic field, ∇⋅(vector)=0

For electrostatic field, ∇×(vector)=0

Substitute y2zax+2(x+1)yzax−(x+1)z2az for D to find ∇⋅D.

∇⋅D=∂∂xDx+∂∂yDy+∂∂zDz=∂∂x(y2z)+∂∂y(2(x+1))+∂∂z(−(x+1))=0+0+0=0

Substitute y2zax+2(x+1)yzax−(x+1)z2az for D to find ∇×D.

∇×D=|axayaz∂∂x∂∂y∂∂zDxDyDz|=|axayaz∂∂x∂∂y∂∂zy2z2(x+1)yz−(x+1)z2|=[(∂∂y(−(x+1)z2)−∂∂z(2(x+1)yz))ax−(∂∂x(−(x+1)z2)−∂∂z(y2z))ay+(∂∂x(2(x+1)yz)−∂∂y(y2z))az]=[((0)−2(x+1)y(1))ax−(−((1)z2+0)−y2(1))ay+((2(1)yz+0)−(2y)z)az]

Simplify the above equation.

∇×D=(−2(x+1)y)ax−(−z2−y2)ay+(2yz−2yz)az=(−2(x+1)y)ax+(z2+y2)ay+(0)az=−2(x+1)yax+(z2+y2)ay≠0

Therefore, for the field D,

∇⋅D=0∇×D≠0

Conclusion:

Thus, the vector D is possibly a magnetostatic field.

(b)

To determine

Find whether the given field E is electrostatic or magnetostatic field in free space.

(b)

Expert Solution

Answer to Problem 41P

The vector E is possibly a magnetostatic field.

Explanation of Solution

Calculation:

Given field is,

E=(z+1)ρcosϕaρ+sinϕρaz

Substitute (z+1)ρcosϕaρ+sinϕρaz for E to find ∇⋅E.

∇⋅E=1ρ∂∂ρ(ρEρ)+1ρ∂∂ϕEϕ+∂∂zEz=1ρ∂∂ρ(ρ((z+1)ρcosϕ))+1ρ∂∂ϕ(0)+∂∂z(sinϕρ)=1ρ∂∂ρ((z+1)cosϕ)+0+0=0

Substitute (z+1)ρcosϕaρ+sinϕρaz for E to find ∇×E.

∇×E=1ρ|aρρaϕaz∂∂ρ∂∂ϕ∂∂z(z+1)ρcosϕρ(0)sinϕρ|=1ρ|aρρaϕaz∂∂ρ∂∂ϕ∂∂z(z+1)ρcosϕ0sinϕρ|=1ρ[(∂∂ϕ(sinϕρ)−∂∂z(0))aρ−(∂∂ρ(sinϕρ)−∂∂z((z+1)ρcosϕ))ρaϕ+(∂∂ρ(0)−∂∂ϕ((z+1)ρcosϕ))az]=1ρ[∂∂ϕ(sinϕρ)aρ−(∂∂ρ(sinϕρ)−∂∂z((z+1)ρcosϕ))ρaϕ−∂∂ϕ((z+1)ρcosϕ)az]

Simplify the above equation.

∇×E=1ρ[cosϕρaρ−ρ(sinϕ(−1ρ2)−(cosϕρ)(1+0))aϕ−(z+1)ρ(−sinϕ)az]=1ρ[cosϕρaρ−ρ(−sinϕρ2−(cosϕρ))aϕ+(z+1)sinϕρaz]=cosϕρ2aρ−(−sinϕρ2−(cosϕρ))aϕ+(z+1)sinϕρ2az≠0

Therefore, for the field E,

∇⋅E=0∇×E≠0

Conclusion:

Thus, the vector E is possibly a magnetostatic field.

(c)

To determine

Find whether the given field F is electrostatic or magnetostatic field in free space.

(c)

Expert Solution

Answer to Problem 41P

The vector F is neither electrostatic nor magnetostatic field.

Explanation of Solution

Calculation:

Given field is,

F=1r2(2cosθar+sinθaθ)=2r2cosθar+1r2sinθaθ

Substitute 2r2cosθar+1r2sinθaθ for F to find ∇⋅F.

∇⋅F=1r2∂∂r(r2Fr)+1rsinθ∂∂θ(sinθFθ)+1rsinθ∂∂ϕ(Fϕ)=1r2∂∂r(r2(2r2cosθ))+1rsinθ∂∂θ(sinθ(1r2sinθ))+1rsinθ∂∂ϕ(0)=1r2∂∂r(2cosθ)+1rsinθ∂∂θ(1r2sin2θ)+0=1r2(0)+1r3sinθ(2sinθcosθ)

Simplify the above equation.

∇⋅F=0+1r3(2cosθ)=2cosθr3≠0

Substitute 2r2cosθar+1r2sinθaθ for F to find ∇×F.

∇×F=1r2sinθ|arraθrsinθaϕ∂∂r∂∂θ∂∂ϕ2r2cosθr(1r2sinθ)0|=1r2sinθ|arraθrsinθaϕ∂∂r∂∂θ∂∂ϕ2r2cosθ1rsinθ0|=1r2sinθ[(∂∂θ(0)−∂∂ϕ(1rsinθ))ar−(∂∂r(0)−∂∂ϕ(2r2cosθ))raθ+(∂∂r(1rsinθ)−∂∂θ(2r2cosθ))rsinθaϕ]=1r2sinθ[(0−(0))ar−(0−(0))raθ+(sinθ(−1r2)−(2r2)(−sinθ))rsinθaϕ]

Simplify the above equation.

∇×F=1r2sinθ[0+0+rsinθ(−1r2sinθ+2r2sinθ)aϕ]=rsinθr2sinθ(−1r2sinθ+2r2sinθ)aϕ=1r3(sinθ)aϕ≠0

Therefore, for the field F,

∇⋅F≠0∇×F≠0

Conclusion:

Thus, the vector F is neither electrostatic nor magnetostatic field.

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Answer 3

Question

Chapter 7, Problem 41P

(a)

To determine

Find whether the given field D is electrostatic or magnetostatic field in free space.

(a)

Expert Solution

Answer to Problem 41P

The vector D is possibly a magnetostatic field.

Explanation of Solution

Calculation:

Given field is,

D=y2zax+2(x+1)yzax−(x+1)z2az

Generally, the vector is a magnetostatic field if its dot product is zero and the vector is an electrostatic field if its cross product is zero. That is,

For magnetostatic field, ∇⋅(vector)=0

For electrostatic field, ∇×(vector)=0

Substitute y2zax+2(x+1)yzax−(x+1)z2az for D to find ∇⋅D.

∇⋅D=∂∂xDx+∂∂yDy+∂∂zDz=∂∂x(y2z)+∂∂y(2(x+1))+∂∂z(−(x+1))=0+0+0=0

Substitute y2zax+2(x+1)yzax−(x+1)z2az for D to find ∇×D.

∇×D=|axayaz∂∂x∂∂y∂∂zDxDyDz|=|axayaz∂∂x∂∂y∂∂zy2z2(x+1)yz−(x+1)z2|=[(∂∂y(−(x+1)z2)−∂∂z(2(x+1)yz))ax−(∂∂x(−(x+1)z2)−∂∂z(y2z))ay+(∂∂x(2(x+1)yz)−∂∂y(y2z))az]=[((0)−2(x+1)y(1))ax−(−((1)z2+0)−y2(1))ay+((2(1)yz+0)−(2y)z)az]

Simplify the above equation.

∇×D=(−2(x+1)y)ax−(−z2−y2)ay+(2yz−2yz)az=(−2(x+1)y)ax+(z2+y2)ay+(0)az=−2(x+1)yax+(z2+y2)ay≠0

Therefore, for the field D,

∇⋅D=0∇×D≠0

Conclusion:

Thus, the vector D is possibly a magnetostatic field.

(b)

To determine

Find whether the given field E is electrostatic or magnetostatic field in free space.

(b)

Expert Solution

Answer to Problem 41P

The vector E is possibly a magnetostatic field.

Explanation of Solution

Calculation:

Given field is,

E=(z+1)ρcosϕaρ+sinϕρaz

Substitute (z+1)ρcosϕaρ+sinϕρaz for E to find ∇⋅E.

∇⋅E=1ρ∂∂ρ(ρEρ)+1ρ∂∂ϕEϕ+∂∂zEz=1ρ∂∂ρ(ρ((z+1)ρcosϕ))+1ρ∂∂ϕ(0)+∂∂z(sinϕρ)=1ρ∂∂ρ((z+1)cosϕ)+0+0=0

Substitute (z+1)ρcosϕaρ+sinϕρaz for E to find ∇×E.

∇×E=1ρ|aρρaϕaz∂∂ρ∂∂ϕ∂∂z(z+1)ρcosϕρ(0)sinϕρ|=1ρ|aρρaϕaz∂∂ρ∂∂ϕ∂∂z(z+1)ρcosϕ0sinϕρ|=1ρ[(∂∂ϕ(sinϕρ)−∂∂z(0))aρ−(∂∂ρ(sinϕρ)−∂∂z((z+1)ρcosϕ))ρaϕ+(∂∂ρ(0)−∂∂ϕ((z+1)ρcosϕ))az]=1ρ[∂∂ϕ(sinϕρ)aρ−(∂∂ρ(sinϕρ)−∂∂z((z+1)ρcosϕ))ρaϕ−∂∂ϕ((z+1)ρcosϕ)az]

Simplify the above equation.

∇×E=1ρ[cosϕρaρ−ρ(sinϕ(−1ρ2)−(cosϕρ)(1+0))aϕ−(z+1)ρ(−sinϕ)az]=1ρ[cosϕρaρ−ρ(−sinϕρ2−(cosϕρ))aϕ+(z+1)sinϕρaz]=cosϕρ2aρ−(−sinϕρ2−(cosϕρ))aϕ+(z+1)sinϕρ2az≠0

Therefore, for the field E,

∇⋅E=0∇×E≠0

Conclusion:

Thus, the vector E is possibly a magnetostatic field.

(c)

To determine

Find whether the given field F is electrostatic or magnetostatic field in free space.

(c)

Expert Solution

Answer to Problem 41P

The vector F is neither electrostatic nor magnetostatic field.

Explanation of Solution

Calculation:

Given field is,

F=1r2(2cosθar+sinθaθ)=2r2cosθar+1r2sinθaθ

Substitute 2r2cosθar+1r2sinθaθ for F to find ∇⋅F.

∇⋅F=1r2∂∂r(r2Fr)+1rsinθ∂∂θ(sinθFθ)+1rsinθ∂∂ϕ(Fϕ)=1r2∂∂r(r2(2r2cosθ))+1rsinθ∂∂θ(sinθ(1r2sinθ))+1rsinθ∂∂ϕ(0)=1r2∂∂r(2cosθ)+1rsinθ∂∂θ(1r2sin2θ)+0=1r2(0)+1r3sinθ(2sinθcosθ)

Simplify the above equation.

∇⋅F=0+1r3(2cosθ)=2cosθr3≠0

Substitute 2r2cosθar+1r2sinθaθ for F to find ∇×F.

∇×F=1r2sinθ|arraθrsinθaϕ∂∂r∂∂θ∂∂ϕ2r2cosθr(1r2sinθ)0|=1r2sinθ|arraθrsinθaϕ∂∂r∂∂θ∂∂ϕ2r2cosθ1rsinθ0|=1r2sinθ[(∂∂θ(0)−∂∂ϕ(1rsinθ))ar−(∂∂r(0)−∂∂ϕ(2r2cosθ))raθ+(∂∂r(1rsinθ)−∂∂θ(2r2cosθ))rsinθaϕ]=1r2sinθ[(0−(0))ar−(0−(0))raθ+(sinθ(−1r2)−(2r2)(−sinθ))rsinθaϕ]

Simplify the above equation.

∇×F=1r2sinθ[0+0+rsinθ(−1r2sinθ+2r2sinθ)aϕ]=rsinθr2sinθ(−1r2sinθ+2r2sinθ)aϕ=1r3(sinθ)aϕ≠0

Therefore, for the field F,

∇⋅F≠0∇×F≠0

Conclusion:

Thus, the vector F is neither electrostatic nor magnetostatic field.

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Answer 4

Question

Chapter 7, Problem 41P

(a)

To determine

Find whether the given field D is electrostatic or magnetostatic field in free space.

(a)

Expert Solution

Answer to Problem 41P

The vector D is possibly a magnetostatic field.

Explanation of Solution

Calculation:

Given field is,

D=y2zax+2(x+1)yzax−(x+1)z2az

Generally, the vector is a magnetostatic field if its dot product is zero and the vector is an electrostatic field if its cross product is zero. That is,

For magnetostatic field, ∇⋅(vector)=0

For electrostatic field, ∇×(vector)=0

Substitute y2zax+2(x+1)yzax−(x+1)z2az for D to find ∇⋅D.

∇⋅D=∂∂xDx+∂∂yDy+∂∂zDz=∂∂x(y2z)+∂∂y(2(x+1))+∂∂z(−(x+1))=0+0+0=0

Substitute y2zax+2(x+1)yzax−(x+1)z2az for D to find ∇×D.

∇×D=|axayaz∂∂x∂∂y∂∂zDxDyDz|=|axayaz∂∂x∂∂y∂∂zy2z2(x+1)yz−(x+1)z2|=[(∂∂y(−(x+1)z2)−∂∂z(2(x+1)yz))ax−(∂∂x(−(x+1)z2)−∂∂z(y2z))ay+(∂∂x(2(x+1)yz)−∂∂y(y2z))az]=[((0)−2(x+1)y(1))ax−(−((1)z2+0)−y2(1))ay+((2(1)yz+0)−(2y)z)az]

Simplify the above equation.

∇×D=(−2(x+1)y)ax−(−z2−y2)ay+(2yz−2yz)az=(−2(x+1)y)ax+(z2+y2)ay+(0)az=−2(x+1)yax+(z2+y2)ay≠0

Therefore, for the field D,

∇⋅D=0∇×D≠0

Conclusion:

Thus, the vector D is possibly a magnetostatic field.

(b)

To determine

Find whether the given field E is electrostatic or magnetostatic field in free space.

(b)

Expert Solution

Answer to Problem 41P

The vector E is possibly a magnetostatic field.

Explanation of Solution

Calculation:

Given field is,

E=(z+1)ρcosϕaρ+sinϕρaz

Substitute (z+1)ρcosϕaρ+sinϕρaz for E to find ∇⋅E.

∇⋅E=1ρ∂∂ρ(ρEρ)+1ρ∂∂ϕEϕ+∂∂zEz=1ρ∂∂ρ(ρ((z+1)ρcosϕ))+1ρ∂∂ϕ(0)+∂∂z(sinϕρ)=1ρ∂∂ρ((z+1)cosϕ)+0+0=0

Substitute (z+1)ρcosϕaρ+sinϕρaz for E to find ∇×E.

∇×E=1ρ|aρρaϕaz∂∂ρ∂∂ϕ∂∂z(z+1)ρcosϕρ(0)sinϕρ|=1ρ|aρρaϕaz∂∂ρ∂∂ϕ∂∂z(z+1)ρcosϕ0sinϕρ|=1ρ[(∂∂ϕ(sinϕρ)−∂∂z(0))aρ−(∂∂ρ(sinϕρ)−∂∂z((z+1)ρcosϕ))ρaϕ+(∂∂ρ(0)−∂∂ϕ((z+1)ρcosϕ))az]=1ρ[∂∂ϕ(sinϕρ)aρ−(∂∂ρ(sinϕρ)−∂∂z((z+1)ρcosϕ))ρaϕ−∂∂ϕ((z+1)ρcosϕ)az]

Simplify the above equation.

∇×E=1ρ[cosϕρaρ−ρ(sinϕ(−1ρ2)−(cosϕρ)(1+0))aϕ−(z+1)ρ(−sinϕ)az]=1ρ[cosϕρaρ−ρ(−sinϕρ2−(cosϕρ))aϕ+(z+1)sinϕρaz]=cosϕρ2aρ−(−sinϕρ2−(cosϕρ))aϕ+(z+1)sinϕρ2az≠0

Therefore, for the field E,

∇⋅E=0∇×E≠0

Conclusion:

Thus, the vector E is possibly a magnetostatic field.

(c)

To determine

Find whether the given field F is electrostatic or magnetostatic field in free space.

(c)

Expert Solution

Answer to Problem 41P

The vector F is neither electrostatic nor magnetostatic field.

Explanation of Solution

Calculation:

Given field is,

F=1r2(2cosθar+sinθaθ)=2r2cosθar+1r2sinθaθ

Substitute 2r2cosθar+1r2sinθaθ for F to find ∇⋅F.

∇⋅F=1r2∂∂r(r2Fr)+1rsinθ∂∂θ(sinθFθ)+1rsinθ∂∂ϕ(Fϕ)=1r2∂∂r(r2(2r2cosθ))+1rsinθ∂∂θ(sinθ(1r2sinθ))+1rsinθ∂∂ϕ(0)=1r2∂∂r(2cosθ)+1rsinθ∂∂θ(1r2sin2θ)+0=1r2(0)+1r3sinθ(2sinθcosθ)

Simplify the above equation.

∇⋅F=0+1r3(2cosθ)=2cosθr3≠0

Substitute 2r2cosθar+1r2sinθaθ for F to find ∇×F.

∇×F=1r2sinθ|arraθrsinθaϕ∂∂r∂∂θ∂∂ϕ2r2cosθr(1r2sinθ)0|=1r2sinθ|arraθrsinθaϕ∂∂r∂∂θ∂∂ϕ2r2cosθ1rsinθ0|=1r2sinθ[(∂∂θ(0)−∂∂ϕ(1rsinθ))ar−(∂∂r(0)−∂∂ϕ(2r2cosθ))raθ+(∂∂r(1rsinθ)−∂∂θ(2r2cosθ))rsinθaϕ]=1r2sinθ[(0−(0))ar−(0−(0))raθ+(sinθ(−1r2)−(2r2)(−sinθ))rsinθaϕ]

Simplify the above equation.

∇×F=1r2sinθ[0+0+rsinθ(−1r2sinθ+2r2sinθ)aϕ]=rsinθr2sinθ(−1r2sinθ+2r2sinθ)aϕ=1r3(sinθ)aϕ≠0

Therefore, for the field F,

∇⋅F≠0∇×F≠0

Conclusion:

Thus, the vector F is neither electrostatic nor magnetostatic field.

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Answer 5

Chapter 7, Problem 41P

(a)

To determine

Find whether the given field D is electrostatic or magnetostatic field in free space.

(a)

Expert Solution

Answer to Problem 41P

The vector D is possibly a magnetostatic field.

Explanation of Solution

Calculation:

Given field is,

D=y2zax+2(x+1)yzax−(x+1)z2az

Generally, the vector is a magnetostatic field if its dot product is zero and the vector is an electrostatic field if its cross product is zero. That is,

For magnetostatic field, ∇⋅(vector)=0

For electrostatic field, ∇×(vector)=0

Substitute y2zax+2(x+1)yzax−(x+1)z2az for D to find ∇⋅D.

∇⋅D=∂∂xDx+∂∂yDy+∂∂zDz=∂∂x(y2z)+∂∂y(2(x+1))+∂∂z(−(x+1))=0+0+0=0

Substitute y2zax+2(x+1)yzax−(x+1)z2az for D to find ∇×D.

∇×D=|axayaz∂∂x∂∂y∂∂zDxDyDz|=|axayaz∂∂x∂∂y∂∂zy2z2(x+1)yz−(x+1)z2|=[(∂∂y(−(x+1)z2)−∂∂z(2(x+1)yz))ax−(∂∂x(−(x+1)z2)−∂∂z(y2z))ay+(∂∂x(2(x+1)yz)−∂∂y(y2z))az]=[((0)−2(x+1)y(1))ax−(−((1)z2+0)−y2(1))ay+((2(1)yz+0)−(2y)z)az]

Simplify the above equation.

∇×D=(−2(x+1)y)ax−(−z2−y2)ay+(2yz−2yz)az=(−2(x+1)y)ax+(z2+y2)ay+(0)az=−2(x+1)yax+(z2+y2)ay≠0

Therefore, for the field D,

∇⋅D=0∇×D≠0

Conclusion:

Thus, the vector D is possibly a magnetostatic field.

(b)

To determine

Find whether the given field E is electrostatic or magnetostatic field in free space.

(b)

Expert Solution

Answer to Problem 41P

The vector E is possibly a magnetostatic field.

Explanation of Solution

Calculation:

Given field is,

E=(z+1)ρcosϕaρ+sinϕρaz

Substitute (z+1)ρcosϕaρ+sinϕρaz for E to find ∇⋅E.

∇⋅E=1ρ∂∂ρ(ρEρ)+1ρ∂∂ϕEϕ+∂∂zEz=1ρ∂∂ρ(ρ((z+1)ρcosϕ))+1ρ∂∂ϕ(0)+∂∂z(sinϕρ)=1ρ∂∂ρ((z+1)cosϕ)+0+0=0

Substitute (z+1)ρcosϕaρ+sinϕρaz for E to find ∇×E.

∇×E=1ρ|aρρaϕaz∂∂ρ∂∂ϕ∂∂z(z+1)ρcosϕρ(0)sinϕρ|=1ρ|aρρaϕaz∂∂ρ∂∂ϕ∂∂z(z+1)ρcosϕ0sinϕρ|=1ρ[(∂∂ϕ(sinϕρ)−∂∂z(0))aρ−(∂∂ρ(sinϕρ)−∂∂z((z+1)ρcosϕ))ρaϕ+(∂∂ρ(0)−∂∂ϕ((z+1)ρcosϕ))az]=1ρ[∂∂ϕ(sinϕρ)aρ−(∂∂ρ(sinϕρ)−∂∂z((z+1)ρcosϕ))ρaϕ−∂∂ϕ((z+1)ρcosϕ)az]

Simplify the above equation.

∇×E=1ρ[cosϕρaρ−ρ(sinϕ(−1ρ2)−(cosϕρ)(1+0))aϕ−(z+1)ρ(−sinϕ)az]=1ρ[cosϕρaρ−ρ(−sinϕρ2−(cosϕρ))aϕ+(z+1)sinϕρaz]=cosϕρ2aρ−(−sinϕρ2−(cosϕρ))aϕ+(z+1)sinϕρ2az≠0

Therefore, for the field E,

∇⋅E=0∇×E≠0

Conclusion:

Thus, the vector E is possibly a magnetostatic field.

(c)

To determine

Find whether the given field F is electrostatic or magnetostatic field in free space.

(c)

Expert Solution

Answer to Problem 41P

The vector F is neither electrostatic nor magnetostatic field.

Explanation of Solution

Calculation:

Given field is,

F=1r2(2cosθar+sinθaθ)=2r2cosθar+1r2sinθaθ

Substitute 2r2cosθar+1r2sinθaθ for F to find ∇⋅F.

∇⋅F=1r2∂∂r(r2Fr)+1rsinθ∂∂θ(sinθFθ)+1rsinθ∂∂ϕ(Fϕ)=1r2∂∂r(r2(2r2cosθ))+1rsinθ∂∂θ(sinθ(1r2sinθ))+1rsinθ∂∂ϕ(0)=1r2∂∂r(2cosθ)+1rsinθ∂∂θ(1r2sin2θ)+0=1r2(0)+1r3sinθ(2sinθcosθ)

Simplify the above equation.

∇⋅F=0+1r3(2cosθ)=2cosθr3≠0

Substitute 2r2cosθar+1r2sinθaθ for F to find ∇×F.

∇×F=1r2sinθ|arraθrsinθaϕ∂∂r∂∂θ∂∂ϕ2r2cosθr(1r2sinθ)0|=1r2sinθ|arraθrsinθaϕ∂∂r∂∂θ∂∂ϕ2r2cosθ1rsinθ0|=1r2sinθ[(∂∂θ(0)−∂∂ϕ(1rsinθ))ar−(∂∂r(0)−∂∂ϕ(2r2cosθ))raθ+(∂∂r(1rsinθ)−∂∂θ(2r2cosθ))rsinθaϕ]=1r2sinθ[(0−(0))ar−(0−(0))raθ+(sinθ(−1r2)−(2r2)(−sinθ))rsinθaϕ]

Simplify the above equation.

∇×F=1r2sinθ[0+0+rsinθ(−1r2sinθ+2r2sinθ)aϕ]=rsinθr2sinθ(−1r2sinθ+2r2sinθ)aϕ=1r3(sinθ)aϕ≠0

Therefore, for the field F,

∇⋅F≠0∇×F≠0

Conclusion:

Thus, the vector F is neither electrostatic nor magnetostatic field.

Answer 6

Chapter 7, Problem 41P

(a)

To determine

Find whether the given field D is electrostatic or magnetostatic field in free space.

(a)

Expert Solution

Answer to Problem 41P

The vector D is possibly a magnetostatic field.

Explanation of Solution

Calculation:

Given field is,

D=y2zax+2(x+1)yzax−(x+1)z2az

Generally, the vector is a magnetostatic field if its dot product is zero and the vector is an electrostatic field if its cross product is zero. That is,

For magnetostatic field, ∇⋅(vector)=0

For electrostatic field, ∇×(vector)=0

Substitute y2zax+2(x+1)yzax−(x+1)z2az for D to find ∇⋅D.

∇⋅D=∂∂xDx+∂∂yDy+∂∂zDz=∂∂x(y2z)+∂∂y(2(x+1))+∂∂z(−(x+1))=0+0+0=0

Substitute y2zax+2(x+1)yzax−(x+1)z2az for D to find ∇×D.

∇×D=|axayaz∂∂x∂∂y∂∂zDxDyDz|=|axayaz∂∂x∂∂y∂∂zy2z2(x+1)yz−(x+1)z2|=[(∂∂y(−(x+1)z2)−∂∂z(2(x+1)yz))ax−(∂∂x(−(x+1)z2)−∂∂z(y2z))ay+(∂∂x(2(x+1)yz)−∂∂y(y2z))az]=[((0)−2(x+1)y(1))ax−(−((1)z2+0)−y2(1))ay+((2(1)yz+0)−(2y)z)az]

Simplify the above equation.

∇×D=(−2(x+1)y)ax−(−z2−y2)ay+(2yz−2yz)az=(−2(x+1)y)ax+(z2+y2)ay+(0)az=−2(x+1)yax+(z2+y2)ay≠0

Therefore, for the field D,

∇⋅D=0∇×D≠0

Conclusion:

Thus, the vector D is possibly a magnetostatic field.

Answer 7

Chapter 7, Problem 41P

(a)

To determine

Find whether the given field D is electrostatic or magnetostatic field in free space.

Answer 8

(a)

Expert Solution

Answer to Problem 41P

The vector D is possibly a magnetostatic field.

Answer 9

(a)

Expert Solution

Answer 10

(a)

Expert Solution

Answer 11

Expert Solution

Answer 12

Explanation of Solution

Calculation:

Given field is,

D=y2zax+2(x+1)yzax−(x+1)z2az

Generally, the vector is a magnetostatic field if its dot product is zero and the vector is an electrostatic field if its cross product is zero. That is,

For magnetostatic field, ∇⋅(vector)=0

For electrostatic field, ∇×(vector)=0

Substitute y2zax+2(x+1)yzax−(x+1)z2az for D to find ∇⋅D.

∇⋅D=∂∂xDx+∂∂yDy+∂∂zDz=∂∂x(y2z)+∂∂y(2(x+1))+∂∂z(−(x+1))=0+0+0=0

Substitute y2zax+2(x+1)yzax−(x+1)z2az for D to find ∇×D.

∇×D=|axayaz∂∂x∂∂y∂∂zDxDyDz|=|axayaz∂∂x∂∂y∂∂zy2z2(x+1)yz−(x+1)z2|=[(∂∂y(−(x+1)z2)−∂∂z(2(x+1)yz))ax−(∂∂x(−(x+1)z2)−∂∂z(y2z))ay+(∂∂x(2(x+1)yz)−∂∂y(y2z))az]=[((0)−2(x+1)y(1))ax−(−((1)z2+0)−y2(1))ay+((2(1)yz+0)−(2y)z)az]

Simplify the above equation.

∇×D=(−2(x+1)y)ax−(−z2−y2)ay+(2yz−2yz)az=(−2(x+1)y)ax+(z2+y2)ay+(0)az=−2(x+1)yax+(z2+y2)ay≠0

Therefore, for the field D,

∇⋅D=0∇×D≠0

Conclusion:

Thus, the vector D is possibly a magnetostatic field.

Answer 13

(b)

To determine

Find whether the given field E is electrostatic or magnetostatic field in free space.

(b)

Expert Solution

Answer to Problem 41P

The vector E is possibly a magnetostatic field.

Explanation of Solution

Calculation:

Given field is,

E=(z+1)ρcosϕaρ+sinϕρaz

Substitute (z+1)ρcosϕaρ+sinϕρaz for E to find ∇⋅E.

∇⋅E=1ρ∂∂ρ(ρEρ)+1ρ∂∂ϕEϕ+∂∂zEz=1ρ∂∂ρ(ρ((z+1)ρcosϕ))+1ρ∂∂ϕ(0)+∂∂z(sinϕρ)=1ρ∂∂ρ((z+1)cosϕ)+0+0=0

Substitute (z+1)ρcosϕaρ+sinϕρaz for E to find ∇×E.

∇×E=1ρ|aρρaϕaz∂∂ρ∂∂ϕ∂∂z(z+1)ρcosϕρ(0)sinϕρ|=1ρ|aρρaϕaz∂∂ρ∂∂ϕ∂∂z(z+1)ρcosϕ0sinϕρ|=1ρ[(∂∂ϕ(sinϕρ)−∂∂z(0))aρ−(∂∂ρ(sinϕρ)−∂∂z((z+1)ρcosϕ))ρaϕ+(∂∂ρ(0)−∂∂ϕ((z+1)ρcosϕ))az]=1ρ[∂∂ϕ(sinϕρ)aρ−(∂∂ρ(sinϕρ)−∂∂z((z+1)ρcosϕ))ρaϕ−∂∂ϕ((z+1)ρcosϕ)az]

Simplify the above equation.

∇×E=1ρ[cosϕρaρ−ρ(sinϕ(−1ρ2)−(cosϕρ)(1+0))aϕ−(z+1)ρ(−sinϕ)az]=1ρ[cosϕρaρ−ρ(−sinϕρ2−(cosϕρ))aϕ+(z+1)sinϕρaz]=cosϕρ2aρ−(−sinϕρ2−(cosϕρ))aϕ+(z+1)sinϕρ2az≠0

Therefore, for the field E,

∇⋅E=0∇×E≠0

Conclusion:

Thus, the vector E is possibly a magnetostatic field.

Answer 14

(b)

To determine

Find whether the given field E is electrostatic or magnetostatic field in free space.

Answer 15

(b)

Expert Solution

Answer to Problem 41P

The vector E is possibly a magnetostatic field.

Answer 16

(b)

Expert Solution

Answer 17

(b)

Expert Solution

Answer 18

Expert Solution

Answer 19

Explanation of Solution

Calculation:

Given field is,

E=(z+1)ρcosϕaρ+sinϕρaz

Substitute (z+1)ρcosϕaρ+sinϕρaz for E to find ∇⋅E.

∇⋅E=1ρ∂∂ρ(ρEρ)+1ρ∂∂ϕEϕ+∂∂zEz=1ρ∂∂ρ(ρ((z+1)ρcosϕ))+1ρ∂∂ϕ(0)+∂∂z(sinϕρ)=1ρ∂∂ρ((z+1)cosϕ)+0+0=0

Substitute (z+1)ρcosϕaρ+sinϕρaz for E to find ∇×E.

∇×E=1ρ|aρρaϕaz∂∂ρ∂∂ϕ∂∂z(z+1)ρcosϕρ(0)sinϕρ|=1ρ|aρρaϕaz∂∂ρ∂∂ϕ∂∂z(z+1)ρcosϕ0sinϕρ|=1ρ[(∂∂ϕ(sinϕρ)−∂∂z(0))aρ−(∂∂ρ(sinϕρ)−∂∂z((z+1)ρcosϕ))ρaϕ+(∂∂ρ(0)−∂∂ϕ((z+1)ρcosϕ))az]=1ρ[∂∂ϕ(sinϕρ)aρ−(∂∂ρ(sinϕρ)−∂∂z((z+1)ρcosϕ))ρaϕ−∂∂ϕ((z+1)ρcosϕ)az]

Simplify the above equation.

∇×E=1ρ[cosϕρaρ−ρ(sinϕ(−1ρ2)−(cosϕρ)(1+0))aϕ−(z+1)ρ(−sinϕ)az]=1ρ[cosϕρaρ−ρ(−sinϕρ2−(cosϕρ))aϕ+(z+1)sinϕρaz]=cosϕρ2aρ−(−sinϕρ2−(cosϕρ))aϕ+(z+1)sinϕρ2az≠0

Therefore, for the field E,

∇⋅E=0∇×E≠0

Conclusion:

Thus, the vector E is possibly a magnetostatic field.

Answer 20

(c)

To determine

Find whether the given field F is electrostatic or magnetostatic field in free space.

(c)

Expert Solution

Answer to Problem 41P

The vector F is neither electrostatic nor magnetostatic field.

Explanation of Solution

Calculation:

Given field is,

F=1r2(2cosθar+sinθaθ)=2r2cosθar+1r2sinθaθ

Substitute 2r2cosθar+1r2sinθaθ for F to find ∇⋅F.

∇⋅F=1r2∂∂r(r2Fr)+1rsinθ∂∂θ(sinθFθ)+1rsinθ∂∂ϕ(Fϕ)=1r2∂∂r(r2(2r2cosθ))+1rsinθ∂∂θ(sinθ(1r2sinθ))+1rsinθ∂∂ϕ(0)=1r2∂∂r(2cosθ)+1rsinθ∂∂θ(1r2sin2θ)+0=1r2(0)+1r3sinθ(2sinθcosθ)

Simplify the above equation.

∇⋅F=0+1r3(2cosθ)=2cosθr3≠0

Substitute 2r2cosθar+1r2sinθaθ for F to find ∇×F.

∇×F=1r2sinθ|arraθrsinθaϕ∂∂r∂∂θ∂∂ϕ2r2cosθr(1r2sinθ)0|=1r2sinθ|arraθrsinθaϕ∂∂r∂∂θ∂∂ϕ2r2cosθ1rsinθ0|=1r2sinθ[(∂∂θ(0)−∂∂ϕ(1rsinθ))ar−(∂∂r(0)−∂∂ϕ(2r2cosθ))raθ+(∂∂r(1rsinθ)−∂∂θ(2r2cosθ))rsinθaϕ]=1r2sinθ[(0−(0))ar−(0−(0))raθ+(sinθ(−1r2)−(2r2)(−sinθ))rsinθaϕ]

Simplify the above equation.

∇×F=1r2sinθ[0+0+rsinθ(−1r2sinθ+2r2sinθ)aϕ]=rsinθr2sinθ(−1r2sinθ+2r2sinθ)aϕ=1r3(sinθ)aϕ≠0

Therefore, for the field F,

∇⋅F≠0∇×F≠0

Conclusion:

Thus, the vector F is neither electrostatic nor magnetostatic field.

Answer 21

(c)

To determine

Find whether the given field F is electrostatic or magnetostatic field in free space.

Answer 22

(c)

Expert Solution

Answer to Problem 41P

The vector F is neither electrostatic nor magnetostatic field.

Answer 23

(c)

Expert Solution

Answer 24

(c)

Expert Solution

Answer 25

Expert Solution

Answer 26

Explanation of Solution

Calculation:

Given field is,

F=1r2(2cosθar+sinθaθ)=2r2cosθar+1r2sinθaθ

Substitute 2r2cosθar+1r2sinθaθ for F to find ∇⋅F.

∇⋅F=1r2∂∂r(r2Fr)+1rsinθ∂∂θ(sinθFθ)+1rsinθ∂∂ϕ(Fϕ)=1r2∂∂r(r2(2r2cosθ))+1rsinθ∂∂θ(sinθ(1r2sinθ))+1rsinθ∂∂ϕ(0)=1r2∂∂r(2cosθ)+1rsinθ∂∂θ(1r2sin2θ)+0=1r2(0)+1r3sinθ(2sinθcosθ)

Simplify the above equation.

∇⋅F=0+1r3(2cosθ)=2cosθr3≠0

Substitute 2r2cosθar+1r2sinθaθ for F to find ∇×F.

∇×F=1r2sinθ|arraθrsinθaϕ∂∂r∂∂θ∂∂ϕ2r2cosθr(1r2sinθ)0|=1r2sinθ|arraθrsinθaϕ∂∂r∂∂θ∂∂ϕ2r2cosθ1rsinθ0|=1r2sinθ[(∂∂θ(0)−∂∂ϕ(1rsinθ))ar−(∂∂r(0)−∂∂ϕ(2r2cosθ))raθ+(∂∂r(1rsinθ)−∂∂θ(2r2cosθ))rsinθaϕ]=1r2sinθ[(0−(0))ar−(0−(0))raθ+(sinθ(−1r2)−(2r2)(−sinθ))rsinθaϕ]

Simplify the above equation.

∇×F=1r2sinθ[0+0+rsinθ(−1r2sinθ+2r2sinθ)aϕ]=rsinθr2sinθ(−1r2sinθ+2r2sinθ)aϕ=1r3(sinθ)aϕ≠0

Therefore, for the field F,

∇⋅F≠0∇×F≠0

Conclusion:

Thus, the vector F is neither electrostatic nor magnetostatic field.

Answer 27

Ch. 7.2 - Prob. 1PE Ch. 7.2 - Prob. 2PE Ch. 7.2 - Prob. 3PE Ch. 7.2 - Prob. 4PE Ch. 7.4 - Prob. 5PE Ch. 7.4 - Prob. 6PE Ch. 7.7 - Prob. 7PE Ch. 7.7 - Prob. 8PE Ch. 7 - Prob. 1RQ Ch. 7 - Prob. 2RQ

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Explanation of Solution

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Explanation of Solution

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