Choose the correct option that provides which potential does not satisfy Laplace’s equation.

Question

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Answer 1

Question

Chapter 6, Problem 4RQ

To determine

Choose the correct option that provides which potential does not satisfy Laplace’s equation.

Expert Solution & Answer

Answer to Problem 4RQ

The correct option is (c)rcosϕ_.

Explanation of Solution

Calculation:

Consider the given potential expression in option (a).

V=2x+5 (1)

Write the expression for ∇V2.

∇V2=∂V∂x2+∂V∂y2+∂V∂z2 (2)

Substitute Equation (1) in (2).

∇V2=∂(2x+5)∂x2+∂(2x+5)∂y2+∂(2x+5)∂z2=∂(2)∂x+∂(0)∂y+∂(0)∂z=0+0+0

∇V2=0 (3)

Write the expression for the Laplace’s equation.

∇V2=0 (4)

Equation (3) is equal to Laplace’s equation in Equation (4). Hence, the given potential equation satisfies the Laplace’s equation.

Consider the given potential expression in option (b).

V=10xy (5)

Substitute Equation (1) in (2).

∇V2=∂(10xy)∂x2+∂(10xy)∂y2+∂(10xy)∂z2=∂(10y)∂x+∂(10x)∂y+∂(0)∂z=0+0+0

∇V2=0 (6)

Equation (6) is equal to Laplace’s equation in Equation (4). Hence, the given potential equation satisfies the Laplace’s equation.

Consider the given potential expression in part (c).

V=rcosϕ (7)

Write the expression for the Laplace’s equation in spherical coordinates.

1r2∂∂r(r2∂V∂r)+1r2sinθ∂∂θ(sinθ∂V∂θ)+1r2sin2θ∂2V∂ϕ2=0 (8)

Substitute Equation (7) in (8).

1r2∂∂r(r2∂(rcosϕ)∂r)+1r2sinθ∂∂θ(sinθ∂(rcosϕ)∂θ)+1r2sin2θ∂2(rcosϕ)∂ϕ2=01r2∂∂r(r2cosϕ)+0+1r2sin2θ∂(−rsinϕ)∂ϕ=01r2(2rcosϕ)+1r2sin2θ(−rcosϕ)=02rcosϕ−cosϕrsin2θ≠0

Hence, the given potential equation does not satisfy the Laplace’s equation.

Consider the given potential expression in part (d).

V=10r (9)

Substitute Equation (9) in (8).

1r2∂∂r(r2∂(10r)∂r)+1r2sinθ∂∂θ(sinθ∂(10r)∂θ)+1r2sin2θ∂2(10r)∂ϕ2=01r2∂∂r(−10r2r2)+0+0=00=0

Hence, the given potential equation satisfies the Laplace’s equation.

Consider the given potential expression in option (e).

V=ρcosϕ+10 (10)

Write the expression for the Laplace’s equation in cylindrical coordinates.

1ρ∂∂ρ(ρ∂V∂ρ)+1ρ2∂2V∂ϕ2+∂2V∂z2=0 (11)

Substitute Equation (10) in (11).

1ρ∂∂ρ(ρ∂(ρcosϕ+10)∂ρ)+1ρ2∂2(ρcosϕ+10)∂ϕ2+∂2(ρcosϕ+10)∂z2=01ρ∂∂ρ(ρcosϕ)+1ρ2∂(−ρsinϕ)∂ϕ+0=01ρ(cosϕ)−1ρ2(−ρcosϕ)=00=0

Hence, the given potential equation satisfies the Laplace’s equation.

Conclusion:

Thus, the correct option is (c)rcosϕ_.

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Answer 2

Question

Chapter 6, Problem 4RQ

To determine

Choose the correct option that provides which potential does not satisfy Laplace’s equation.

Expert Solution & Answer

Answer to Problem 4RQ

The correct option is (c)rcosϕ_.

Explanation of Solution

Calculation:

Consider the given potential expression in option (a).

V=2x+5 (1)

Write the expression for ∇V2.

∇V2=∂V∂x2+∂V∂y2+∂V∂z2 (2)

Substitute Equation (1) in (2).

∇V2=∂(2x+5)∂x2+∂(2x+5)∂y2+∂(2x+5)∂z2=∂(2)∂x+∂(0)∂y+∂(0)∂z=0+0+0

∇V2=0 (3)

Write the expression for the Laplace’s equation.

∇V2=0 (4)

Equation (3) is equal to Laplace’s equation in Equation (4). Hence, the given potential equation satisfies the Laplace’s equation.

Consider the given potential expression in option (b).

V=10xy (5)

Substitute Equation (1) in (2).

∇V2=∂(10xy)∂x2+∂(10xy)∂y2+∂(10xy)∂z2=∂(10y)∂x+∂(10x)∂y+∂(0)∂z=0+0+0

∇V2=0 (6)

Equation (6) is equal to Laplace’s equation in Equation (4). Hence, the given potential equation satisfies the Laplace’s equation.

Consider the given potential expression in part (c).

V=rcosϕ (7)

Write the expression for the Laplace’s equation in spherical coordinates.

1r2∂∂r(r2∂V∂r)+1r2sinθ∂∂θ(sinθ∂V∂θ)+1r2sin2θ∂2V∂ϕ2=0 (8)

Substitute Equation (7) in (8).

1r2∂∂r(r2∂(rcosϕ)∂r)+1r2sinθ∂∂θ(sinθ∂(rcosϕ)∂θ)+1r2sin2θ∂2(rcosϕ)∂ϕ2=01r2∂∂r(r2cosϕ)+0+1r2sin2θ∂(−rsinϕ)∂ϕ=01r2(2rcosϕ)+1r2sin2θ(−rcosϕ)=02rcosϕ−cosϕrsin2θ≠0

Hence, the given potential equation does not satisfy the Laplace’s equation.

Consider the given potential expression in part (d).

V=10r (9)

Substitute Equation (9) in (8).

1r2∂∂r(r2∂(10r)∂r)+1r2sinθ∂∂θ(sinθ∂(10r)∂θ)+1r2sin2θ∂2(10r)∂ϕ2=01r2∂∂r(−10r2r2)+0+0=00=0

Hence, the given potential equation satisfies the Laplace’s equation.

Consider the given potential expression in option (e).

V=ρcosϕ+10 (10)

Write the expression for the Laplace’s equation in cylindrical coordinates.

1ρ∂∂ρ(ρ∂V∂ρ)+1ρ2∂2V∂ϕ2+∂2V∂z2=0 (11)

Substitute Equation (10) in (11).

1ρ∂∂ρ(ρ∂(ρcosϕ+10)∂ρ)+1ρ2∂2(ρcosϕ+10)∂ϕ2+∂2(ρcosϕ+10)∂z2=01ρ∂∂ρ(ρcosϕ)+1ρ2∂(−ρsinϕ)∂ϕ+0=01ρ(cosϕ)−1ρ2(−ρcosϕ)=00=0

Hence, the given potential equation satisfies the Laplace’s equation.

Conclusion:

Thus, the correct option is (c)rcosϕ_.

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Answer 3

Question

Chapter 6, Problem 4RQ

To determine

Choose the correct option that provides which potential does not satisfy Laplace’s equation.

Expert Solution & Answer

Answer to Problem 4RQ

The correct option is (c)rcosϕ_.

Explanation of Solution

Calculation:

Consider the given potential expression in option (a).

V=2x+5 (1)

Write the expression for ∇V2.

∇V2=∂V∂x2+∂V∂y2+∂V∂z2 (2)

Substitute Equation (1) in (2).

∇V2=∂(2x+5)∂x2+∂(2x+5)∂y2+∂(2x+5)∂z2=∂(2)∂x+∂(0)∂y+∂(0)∂z=0+0+0

∇V2=0 (3)

Write the expression for the Laplace’s equation.

∇V2=0 (4)

Equation (3) is equal to Laplace’s equation in Equation (4). Hence, the given potential equation satisfies the Laplace’s equation.

Consider the given potential expression in option (b).

V=10xy (5)

Substitute Equation (1) in (2).

∇V2=∂(10xy)∂x2+∂(10xy)∂y2+∂(10xy)∂z2=∂(10y)∂x+∂(10x)∂y+∂(0)∂z=0+0+0

∇V2=0 (6)

Equation (6) is equal to Laplace’s equation in Equation (4). Hence, the given potential equation satisfies the Laplace’s equation.

Consider the given potential expression in part (c).

V=rcosϕ (7)

Write the expression for the Laplace’s equation in spherical coordinates.

1r2∂∂r(r2∂V∂r)+1r2sinθ∂∂θ(sinθ∂V∂θ)+1r2sin2θ∂2V∂ϕ2=0 (8)

Substitute Equation (7) in (8).

1r2∂∂r(r2∂(rcosϕ)∂r)+1r2sinθ∂∂θ(sinθ∂(rcosϕ)∂θ)+1r2sin2θ∂2(rcosϕ)∂ϕ2=01r2∂∂r(r2cosϕ)+0+1r2sin2θ∂(−rsinϕ)∂ϕ=01r2(2rcosϕ)+1r2sin2θ(−rcosϕ)=02rcosϕ−cosϕrsin2θ≠0

Hence, the given potential equation does not satisfy the Laplace’s equation.

Consider the given potential expression in part (d).

V=10r (9)

Substitute Equation (9) in (8).

1r2∂∂r(r2∂(10r)∂r)+1r2sinθ∂∂θ(sinθ∂(10r)∂θ)+1r2sin2θ∂2(10r)∂ϕ2=01r2∂∂r(−10r2r2)+0+0=00=0

Hence, the given potential equation satisfies the Laplace’s equation.

Consider the given potential expression in option (e).

V=ρcosϕ+10 (10)

Write the expression for the Laplace’s equation in cylindrical coordinates.

1ρ∂∂ρ(ρ∂V∂ρ)+1ρ2∂2V∂ϕ2+∂2V∂z2=0 (11)

Substitute Equation (10) in (11).

1ρ∂∂ρ(ρ∂(ρcosϕ+10)∂ρ)+1ρ2∂2(ρcosϕ+10)∂ϕ2+∂2(ρcosϕ+10)∂z2=01ρ∂∂ρ(ρcosϕ)+1ρ2∂(−ρsinϕ)∂ϕ+0=01ρ(cosϕ)−1ρ2(−ρcosϕ)=00=0

Hence, the given potential equation satisfies the Laplace’s equation.

Conclusion:

Thus, the correct option is (c)rcosϕ_.

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Answer 4

Question

Chapter 6, Problem 4RQ

To determine

Choose the correct option that provides which potential does not satisfy Laplace’s equation.

Expert Solution & Answer

Answer to Problem 4RQ

The correct option is (c)rcosϕ_.

Explanation of Solution

Calculation:

Consider the given potential expression in option (a).

V=2x+5 (1)

Write the expression for ∇V2.

∇V2=∂V∂x2+∂V∂y2+∂V∂z2 (2)

Substitute Equation (1) in (2).

∇V2=∂(2x+5)∂x2+∂(2x+5)∂y2+∂(2x+5)∂z2=∂(2)∂x+∂(0)∂y+∂(0)∂z=0+0+0

∇V2=0 (3)

Write the expression for the Laplace’s equation.

∇V2=0 (4)

Equation (3) is equal to Laplace’s equation in Equation (4). Hence, the given potential equation satisfies the Laplace’s equation.

Consider the given potential expression in option (b).

V=10xy (5)

Substitute Equation (1) in (2).

∇V2=∂(10xy)∂x2+∂(10xy)∂y2+∂(10xy)∂z2=∂(10y)∂x+∂(10x)∂y+∂(0)∂z=0+0+0

∇V2=0 (6)

Equation (6) is equal to Laplace’s equation in Equation (4). Hence, the given potential equation satisfies the Laplace’s equation.

Consider the given potential expression in part (c).

V=rcosϕ (7)

Write the expression for the Laplace’s equation in spherical coordinates.

1r2∂∂r(r2∂V∂r)+1r2sinθ∂∂θ(sinθ∂V∂θ)+1r2sin2θ∂2V∂ϕ2=0 (8)

Substitute Equation (7) in (8).

1r2∂∂r(r2∂(rcosϕ)∂r)+1r2sinθ∂∂θ(sinθ∂(rcosϕ)∂θ)+1r2sin2θ∂2(rcosϕ)∂ϕ2=01r2∂∂r(r2cosϕ)+0+1r2sin2θ∂(−rsinϕ)∂ϕ=01r2(2rcosϕ)+1r2sin2θ(−rcosϕ)=02rcosϕ−cosϕrsin2θ≠0

Hence, the given potential equation does not satisfy the Laplace’s equation.

Consider the given potential expression in part (d).

V=10r (9)

Substitute Equation (9) in (8).

1r2∂∂r(r2∂(10r)∂r)+1r2sinθ∂∂θ(sinθ∂(10r)∂θ)+1r2sin2θ∂2(10r)∂ϕ2=01r2∂∂r(−10r2r2)+0+0=00=0

Hence, the given potential equation satisfies the Laplace’s equation.

Consider the given potential expression in option (e).

V=ρcosϕ+10 (10)

Write the expression for the Laplace’s equation in cylindrical coordinates.

1ρ∂∂ρ(ρ∂V∂ρ)+1ρ2∂2V∂ϕ2+∂2V∂z2=0 (11)

Substitute Equation (10) in (11).

1ρ∂∂ρ(ρ∂(ρcosϕ+10)∂ρ)+1ρ2∂2(ρcosϕ+10)∂ϕ2+∂2(ρcosϕ+10)∂z2=01ρ∂∂ρ(ρcosϕ)+1ρ2∂(−ρsinϕ)∂ϕ+0=01ρ(cosϕ)−1ρ2(−ρcosϕ)=00=0

Hence, the given potential equation satisfies the Laplace’s equation.

Conclusion:

Thus, the correct option is (c)rcosϕ_.

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Answer 5

Chapter 6, Problem 4RQ

To determine

Choose the correct option that provides which potential does not satisfy Laplace’s equation.

Expert Solution & Answer

Answer to Problem 4RQ

The correct option is (c)rcosϕ_.

Explanation of Solution

Calculation:

Consider the given potential expression in option (a).

V=2x+5 (1)

Write the expression for ∇V2.

∇V2=∂V∂x2+∂V∂y2+∂V∂z2 (2)

Substitute Equation (1) in (2).

∇V2=∂(2x+5)∂x2+∂(2x+5)∂y2+∂(2x+5)∂z2=∂(2)∂x+∂(0)∂y+∂(0)∂z=0+0+0

∇V2=0 (3)

Write the expression for the Laplace’s equation.

∇V2=0 (4)

Equation (3) is equal to Laplace’s equation in Equation (4). Hence, the given potential equation satisfies the Laplace’s equation.

Consider the given potential expression in option (b).

V=10xy (5)

Substitute Equation (1) in (2).

∇V2=∂(10xy)∂x2+∂(10xy)∂y2+∂(10xy)∂z2=∂(10y)∂x+∂(10x)∂y+∂(0)∂z=0+0+0

∇V2=0 (6)

Equation (6) is equal to Laplace’s equation in Equation (4). Hence, the given potential equation satisfies the Laplace’s equation.

Consider the given potential expression in part (c).

V=rcosϕ (7)

Write the expression for the Laplace’s equation in spherical coordinates.

1r2∂∂r(r2∂V∂r)+1r2sinθ∂∂θ(sinθ∂V∂θ)+1r2sin2θ∂2V∂ϕ2=0 (8)

Substitute Equation (7) in (8).

1r2∂∂r(r2∂(rcosϕ)∂r)+1r2sinθ∂∂θ(sinθ∂(rcosϕ)∂θ)+1r2sin2θ∂2(rcosϕ)∂ϕ2=01r2∂∂r(r2cosϕ)+0+1r2sin2θ∂(−rsinϕ)∂ϕ=01r2(2rcosϕ)+1r2sin2θ(−rcosϕ)=02rcosϕ−cosϕrsin2θ≠0

Hence, the given potential equation does not satisfy the Laplace’s equation.

Consider the given potential expression in part (d).

V=10r (9)

Substitute Equation (9) in (8).

1r2∂∂r(r2∂(10r)∂r)+1r2sinθ∂∂θ(sinθ∂(10r)∂θ)+1r2sin2θ∂2(10r)∂ϕ2=01r2∂∂r(−10r2r2)+0+0=00=0

Hence, the given potential equation satisfies the Laplace’s equation.

Consider the given potential expression in option (e).

V=ρcosϕ+10 (10)

Write the expression for the Laplace’s equation in cylindrical coordinates.

1ρ∂∂ρ(ρ∂V∂ρ)+1ρ2∂2V∂ϕ2+∂2V∂z2=0 (11)

Substitute Equation (10) in (11).

1ρ∂∂ρ(ρ∂(ρcosϕ+10)∂ρ)+1ρ2∂2(ρcosϕ+10)∂ϕ2+∂2(ρcosϕ+10)∂z2=01ρ∂∂ρ(ρcosϕ)+1ρ2∂(−ρsinϕ)∂ϕ+0=01ρ(cosϕ)−1ρ2(−ρcosϕ)=00=0

Hence, the given potential equation satisfies the Laplace’s equation.

Conclusion:

Thus, the correct option is (c)rcosϕ_.

Answer 6

Chapter 6, Problem 4RQ

To determine

Choose the correct option that provides which potential does not satisfy Laplace’s equation.

Expert Solution & Answer

Answer to Problem 4RQ

The correct option is (c)rcosϕ_.

Explanation of Solution

Calculation:

Consider the given potential expression in option (a).

V=2x+5 (1)

Write the expression for ∇V2.

∇V2=∂V∂x2+∂V∂y2+∂V∂z2 (2)

Substitute Equation (1) in (2).

∇V2=∂(2x+5)∂x2+∂(2x+5)∂y2+∂(2x+5)∂z2=∂(2)∂x+∂(0)∂y+∂(0)∂z=0+0+0

∇V2=0 (3)

Write the expression for the Laplace’s equation.

∇V2=0 (4)

Equation (3) is equal to Laplace’s equation in Equation (4). Hence, the given potential equation satisfies the Laplace’s equation.

Consider the given potential expression in option (b).

V=10xy (5)

Substitute Equation (1) in (2).

∇V2=∂(10xy)∂x2+∂(10xy)∂y2+∂(10xy)∂z2=∂(10y)∂x+∂(10x)∂y+∂(0)∂z=0+0+0

∇V2=0 (6)

Equation (6) is equal to Laplace’s equation in Equation (4). Hence, the given potential equation satisfies the Laplace’s equation.

Consider the given potential expression in part (c).

V=rcosϕ (7)

Write the expression for the Laplace’s equation in spherical coordinates.

1r2∂∂r(r2∂V∂r)+1r2sinθ∂∂θ(sinθ∂V∂θ)+1r2sin2θ∂2V∂ϕ2=0 (8)

Substitute Equation (7) in (8).

1r2∂∂r(r2∂(rcosϕ)∂r)+1r2sinθ∂∂θ(sinθ∂(rcosϕ)∂θ)+1r2sin2θ∂2(rcosϕ)∂ϕ2=01r2∂∂r(r2cosϕ)+0+1r2sin2θ∂(−rsinϕ)∂ϕ=01r2(2rcosϕ)+1r2sin2θ(−rcosϕ)=02rcosϕ−cosϕrsin2θ≠0

Hence, the given potential equation does not satisfy the Laplace’s equation.

Consider the given potential expression in part (d).

V=10r (9)

Substitute Equation (9) in (8).

1r2∂∂r(r2∂(10r)∂r)+1r2sinθ∂∂θ(sinθ∂(10r)∂θ)+1r2sin2θ∂2(10r)∂ϕ2=01r2∂∂r(−10r2r2)+0+0=00=0

Hence, the given potential equation satisfies the Laplace’s equation.

Consider the given potential expression in option (e).

V=ρcosϕ+10 (10)

Write the expression for the Laplace’s equation in cylindrical coordinates.

1ρ∂∂ρ(ρ∂V∂ρ)+1ρ2∂2V∂ϕ2+∂2V∂z2=0 (11)

Substitute Equation (10) in (11).

1ρ∂∂ρ(ρ∂(ρcosϕ+10)∂ρ)+1ρ2∂2(ρcosϕ+10)∂ϕ2+∂2(ρcosϕ+10)∂z2=01ρ∂∂ρ(ρcosϕ)+1ρ2∂(−ρsinϕ)∂ϕ+0=01ρ(cosϕ)−1ρ2(−ρcosϕ)=00=0

Hence, the given potential equation satisfies the Laplace’s equation.

Conclusion:

Thus, the correct option is (c)rcosϕ_.

Answer 7

Chapter 6, Problem 4RQ

To determine

Choose the correct option that provides which potential does not satisfy Laplace’s equation.

Answer 8

Expert Solution & Answer

Answer to Problem 4RQ

The correct option is (c)rcosϕ_.

Answer 9

Expert Solution & Answer

Answer 10

Expert Solution & Answer

Answer 11

Explanation of Solution

Calculation:

Consider the given potential expression in option (a).

V=2x+5 (1)

Write the expression for ∇V2.

∇V2=∂V∂x2+∂V∂y2+∂V∂z2 (2)

Substitute Equation (1) in (2).

∇V2=∂(2x+5)∂x2+∂(2x+5)∂y2+∂(2x+5)∂z2=∂(2)∂x+∂(0)∂y+∂(0)∂z=0+0+0

∇V2=0 (3)

Write the expression for the Laplace’s equation.

∇V2=0 (4)

Equation (3) is equal to Laplace’s equation in Equation (4). Hence, the given potential equation satisfies the Laplace’s equation.

Consider the given potential expression in option (b).

V=10xy (5)

Substitute Equation (1) in (2).

∇V2=∂(10xy)∂x2+∂(10xy)∂y2+∂(10xy)∂z2=∂(10y)∂x+∂(10x)∂y+∂(0)∂z=0+0+0

∇V2=0 (6)

Equation (6) is equal to Laplace’s equation in Equation (4). Hence, the given potential equation satisfies the Laplace’s equation.

Consider the given potential expression in part (c).

V=rcosϕ (7)

Write the expression for the Laplace’s equation in spherical coordinates.

1r2∂∂r(r2∂V∂r)+1r2sinθ∂∂θ(sinθ∂V∂θ)+1r2sin2θ∂2V∂ϕ2=0 (8)

Substitute Equation (7) in (8).

1r2∂∂r(r2∂(rcosϕ)∂r)+1r2sinθ∂∂θ(sinθ∂(rcosϕ)∂θ)+1r2sin2θ∂2(rcosϕ)∂ϕ2=01r2∂∂r(r2cosϕ)+0+1r2sin2θ∂(−rsinϕ)∂ϕ=01r2(2rcosϕ)+1r2sin2θ(−rcosϕ)=02rcosϕ−cosϕrsin2θ≠0