(a) The voltage V .

Question

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Answer 1

Question

Chapter 6, Problem 6.34P

To determine

(a)

The voltage V.

Expert Solution

Answer to Problem 6.34P

The final voltages are:

V1=−ρ0z22ε+ρ0bz2ε[b+2εr(d−b)b+εr(d−b)] and V2=ρ0bε0(d−z)−ρ0b2ε0[b+2εr(d−b)b+εr(d−b)](d−z).

Explanation of Solution

Calculation:

The Poisson's equation is defined for z<b boundary condition (where b is the radius of conductor).

The Poisson's equation is written as,

d2V1dz2=−ρ0ε ...... (1)

Here,

ρ0 is the charge density.

ε is the permittivity.

z is the direction along z axis.

V1 is the voltage for case z<b.

Integrate the equation (1) with respect to z.

dV1dz=−ρ0zε+C1 ...... (2)

The Laplace's equation is written as,

d2V2dz2=0 ...... (3)

Integrate the equation (3) with respect to z.

dV2dz=C1′ ...... (4)

Substitute z=b in equation (2).

dV1dz=−ρ0bε+C1 ...... (5)

Simplified the equation (5) as,

εdV1dz=−ρ0b+εC1 ...... (6)

Equation (3) is multiplied with ε0 on both side as,

ε0dV2dz=ε0C1′ ...... (7)

If equation (6) and equation (7) is equal, then it is written as,

−ρ0b+εC1=ε0C1′ ..... (8)

Simplified the equation (8) as,

C1′=−ρ0bε0+εC1ε0

Substitute −ρ0bε0+εC1ε0 for C1′ in equation (4).

dV2dz=−ρ0bε0+εC1ε0 ..... (9)

Integrate the equation (2) with respect to z as,

V1=−ρ0z22ε+C1z+C2 ...... (10)

Integrate the equation (9) with respect to z as,

V2=−ρ0bzε0+εC1zε0+C2′ ..... (11)

Substitute d for z and 0 for V2 in equation (11).

0=−ρ0bdε0+εC1dε0+C2′ ..... (12)

Equation (12) is simplified as,

C2′=ρ0bdε0−εC1dε0

Substitute 0 for C2 in equation (10).

V1=−ρ0z22ε+C1z ...... (13)

Substitute ρ0bdε0−εC1dε0 for C2′ in equation (11).

V2=−ρ0bzε0+εC1zε0+ρ0bdε0−εC1dε0=ρ0bε0(d−z)−εC1ε0(d−z) ...... (14)

If equation (13) and equation (14) is equal, then it is written as,

−ρ0z22ε+C1z=ρ0bε0(d−z)−εC1ε0(d−z) ..... (15)

Substitute b for z and εεr for ε0 in equation (15).

C1=ρ0b2ε[b+2εr(d−b)b+εr(d−b)]

Substitute ρ0b2ε[b+2εr(d−b)b+εr(d−b)] for C1 in equation (13)

V1=−ρ0z22ε+ρ0bz2ε[b+2εr(d−b)b+εr(d−b)] ...... (16)

Substitute ρ0b2ε[b+2εr(d−b)b+εr(d−b)] for C1 in equation (14)

V2=ρ0bε0(d−z)−ρ0b2ε0[b+2εr(d−b)b+εr(d−b)](d−z) ...... (17)

Conclusion:

Therefore, the final voltages are V1=−ρ0z22ε+ρ0bz2ε[b+2εr(d−b)b+εr(d−b)] and V2=ρ0bε0(d−z)−ρ0b2ε0[b+2εr(d−b)b+εr(d−b)](d−z).

To determine

(b)

The electric field intensity.

Expert Solution

Answer to Problem 6.34P

The electric field E1 is [ρ0zε+ρ0b2ε[b+2εr( d−b)b+εr( d−b)]]az and electric field E2 is ρ0b22ε0[1b+εr(d−b)]az.

Explanation of Solution

Calculation:

Differentiate the equation (16) with respect to z as,

dV1dz=−ρ0zε+ρ0b2ε[b+2εr(d−b)b+εr(d−b)]

Differentiate the equation (17) with respect to z as,

dV2dz=−ρ0b22ε0[1b+εr(d−b)]

The electric field intensity E1 is written as,

E1=−dV1dzaz ...... (18)

Here,

az is the plane along z axis.

Substitute −ρ0zε+ρ0b2ε[b+2εr(d−b)b+εr(d−b)] for dV1dz in equation (18).

E1=−[− ρ 0zε+ ρ 0b2ε[ b+2 ε r ( d−b ) b+ ε r ( d−b )]]az=[ ρ 0zε+ ρ 0b2ε[ b+2 ε r ( d−b ) b+ ε r ( d−b )]]az

The electric field intensity E2 is written as,

E2=−dV2dzaz ...... (19)

Substitute −ρ0b22ε0[1b+εr(d−b)] for dV2dz in equation (19).

E2=−[− ρ 0 b 22 ε 0[1 b+ ε r ( d−b )]]az=ρ0b22ε0[1b+ ε r( d−b)]az

Conclusion:

Therefore, the electric field E1 is [ρ0zε+ρ0b2ε[b+2εr( d−b)b+εr( d−b)]]az and electric field E2 is ρ0b22ε0[1b+εr(d−b)]az.

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Answer 2

Question

Chapter 6, Problem 6.34P

To determine

(a)

The voltage V.

Expert Solution

Answer to Problem 6.34P

The final voltages are:

V1=−ρ0z22ε+ρ0bz2ε[b+2εr(d−b)b+εr(d−b)] and V2=ρ0bε0(d−z)−ρ0b2ε0[b+2εr(d−b)b+εr(d−b)](d−z).

Explanation of Solution

Calculation:

The Poisson's equation is defined for z<b boundary condition (where b is the radius of conductor).

The Poisson's equation is written as,

d2V1dz2=−ρ0ε ...... (1)

Here,

ρ0 is the charge density.

ε is the permittivity.

z is the direction along z axis.

V1 is the voltage for case z<b.

Integrate the equation (1) with respect to z.

dV1dz=−ρ0zε+C1 ...... (2)

The Laplace's equation is written as,

d2V2dz2=0 ...... (3)

Integrate the equation (3) with respect to z.

dV2dz=C1′ ...... (4)

Substitute z=b in equation (2).

dV1dz=−ρ0bε+C1 ...... (5)

Simplified the equation (5) as,

εdV1dz=−ρ0b+εC1 ...... (6)

Equation (3) is multiplied with ε0 on both side as,

ε0dV2dz=ε0C1′ ...... (7)

If equation (6) and equation (7) is equal, then it is written as,

−ρ0b+εC1=ε0C1′ ..... (8)

Simplified the equation (8) as,

C1′=−ρ0bε0+εC1ε0

Substitute −ρ0bε0+εC1ε0 for C1′ in equation (4).

dV2dz=−ρ0bε0+εC1ε0 ..... (9)

Integrate the equation (2) with respect to z as,

V1=−ρ0z22ε+C1z+C2 ...... (10)

Integrate the equation (9) with respect to z as,

V2=−ρ0bzε0+εC1zε0+C2′ ..... (11)

Substitute d for z and 0 for V2 in equation (11).

0=−ρ0bdε0+εC1dε0+C2′ ..... (12)

Equation (12) is simplified as,

C2′=ρ0bdε0−εC1dε0

Substitute 0 for C2 in equation (10).

V1=−ρ0z22ε+C1z ...... (13)

Substitute ρ0bdε0−εC1dε0 for C2′ in equation (11).

V2=−ρ0bzε0+εC1zε0+ρ0bdε0−εC1dε0=ρ0bε0(d−z)−εC1ε0(d−z) ...... (14)

If equation (13) and equation (14) is equal, then it is written as,

−ρ0z22ε+C1z=ρ0bε0(d−z)−εC1ε0(d−z) ..... (15)

Substitute b for z and εεr for ε0 in equation (15).

C1=ρ0b2ε[b+2εr(d−b)b+εr(d−b)]

Substitute ρ0b2ε[b+2εr(d−b)b+εr(d−b)] for C1 in equation (13)

V1=−ρ0z22ε+ρ0bz2ε[b+2εr(d−b)b+εr(d−b)] ...... (16)

Substitute ρ0b2ε[b+2εr(d−b)b+εr(d−b)] for C1 in equation (14)

V2=ρ0bε0(d−z)−ρ0b2ε0[b+2εr(d−b)b+εr(d−b)](d−z) ...... (17)

Conclusion:

Therefore, the final voltages are V1=−ρ0z22ε+ρ0bz2ε[b+2εr(d−b)b+εr(d−b)] and V2=ρ0bε0(d−z)−ρ0b2ε0[b+2εr(d−b)b+εr(d−b)](d−z).

To determine

(b)

The electric field intensity.

Expert Solution

Answer to Problem 6.34P

The electric field E1 is [ρ0zε+ρ0b2ε[b+2εr( d−b)b+εr( d−b)]]az and electric field E2 is ρ0b22ε0[1b+εr(d−b)]az.

Explanation of Solution

Calculation:

Differentiate the equation (16) with respect to z as,

dV1dz=−ρ0zε+ρ0b2ε[b+2εr(d−b)b+εr(d−b)]

Differentiate the equation (17) with respect to z as,

dV2dz=−ρ0b22ε0[1b+εr(d−b)]

The electric field intensity E1 is written as,

E1=−dV1dzaz ...... (18)

Here,

az is the plane along z axis.

Substitute −ρ0zε+ρ0b2ε[b+2εr(d−b)b+εr(d−b)] for dV1dz in equation (18).

E1=−[− ρ 0zε+ ρ 0b2ε[ b+2 ε r ( d−b ) b+ ε r ( d−b )]]az=[ ρ 0zε+ ρ 0b2ε[ b+2 ε r ( d−b ) b+ ε r ( d−b )]]az

The electric field intensity E2 is written as,

E2=−dV2dzaz ...... (19)

Substitute −ρ0b22ε0[1b+εr(d−b)] for dV2dz in equation (19).

E2=−[− ρ 0 b 22 ε 0[1 b+ ε r ( d−b )]]az=ρ0b22ε0[1b+ ε r( d−b)]az

Conclusion:

Therefore, the electric field E1 is [ρ0zε+ρ0b2ε[b+2εr( d−b)b+εr( d−b)]]az and electric field E2 is ρ0b22ε0[1b+εr(d−b)]az.

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Answer 3

Question

Chapter 6, Problem 6.34P

To determine

(a)

The voltage V.

Expert Solution

Answer to Problem 6.34P

The final voltages are:

V1=−ρ0z22ε+ρ0bz2ε[b+2εr(d−b)b+εr(d−b)] and V2=ρ0bε0(d−z)−ρ0b2ε0[b+2εr(d−b)b+εr(d−b)](d−z).

Explanation of Solution

Calculation:

The Poisson's equation is defined for z<b boundary condition (where b is the radius of conductor).

The Poisson's equation is written as,

d2V1dz2=−ρ0ε ...... (1)

Here,

ρ0 is the charge density.

ε is the permittivity.

z is the direction along z axis.

V1 is the voltage for case z<b.

Integrate the equation (1) with respect to z.

dV1dz=−ρ0zε+C1 ...... (2)

The Laplace's equation is written as,

d2V2dz2=0 ...... (3)

Integrate the equation (3) with respect to z.

dV2dz=C1′ ...... (4)

Substitute z=b in equation (2).

dV1dz=−ρ0bε+C1 ...... (5)

Simplified the equation (5) as,

εdV1dz=−ρ0b+εC1 ...... (6)

Equation (3) is multiplied with ε0 on both side as,

ε0dV2dz=ε0C1′ ...... (7)

If equation (6) and equation (7) is equal, then it is written as,

−ρ0b+εC1=ε0C1′ ..... (8)

Simplified the equation (8) as,

C1′=−ρ0bε0+εC1ε0

Substitute −ρ0bε0+εC1ε0 for C1′ in equation (4).

dV2dz=−ρ0bε0+εC1ε0 ..... (9)

Integrate the equation (2) with respect to z as,

V1=−ρ0z22ε+C1z+C2 ...... (10)

Integrate the equation (9) with respect to z as,

V2=−ρ0bzε0+εC1zε0+C2′ ..... (11)

Substitute d for z and 0 for V2 in equation (11).

0=−ρ0bdε0+εC1dε0+C2′ ..... (12)

Equation (12) is simplified as,

C2′=ρ0bdε0−εC1dε0

Substitute 0 for C2 in equation (10).

V1=−ρ0z22ε+C1z ...... (13)

Substitute ρ0bdε0−εC1dε0 for C2′ in equation (11).

V2=−ρ0bzε0+εC1zε0+ρ0bdε0−εC1dε0=ρ0bε0(d−z)−εC1ε0(d−z) ...... (14)

If equation (13) and equation (14) is equal, then it is written as,

−ρ0z22ε+C1z=ρ0bε0(d−z)−εC1ε0(d−z) ..... (15)

Substitute b for z and εεr for ε0 in equation (15).

C1=ρ0b2ε[b+2εr(d−b)b+εr(d−b)]

Substitute ρ0b2ε[b+2εr(d−b)b+εr(d−b)] for C1 in equation (13)

V1=−ρ0z22ε+ρ0bz2ε[b+2εr(d−b)b+εr(d−b)] ...... (16)

Substitute ρ0b2ε[b+2εr(d−b)b+εr(d−b)] for C1 in equation (14)

V2=ρ0bε0(d−z)−ρ0b2ε0[b+2εr(d−b)b+εr(d−b)](d−z) ...... (17)

Conclusion:

Therefore, the final voltages are V1=−ρ0z22ε+ρ0bz2ε[b+2εr(d−b)b+εr(d−b)] and V2=ρ0bε0(d−z)−ρ0b2ε0[b+2εr(d−b)b+εr(d−b)](d−z).

To determine

(b)

The electric field intensity.

Expert Solution

Answer to Problem 6.34P

The electric field E1 is [ρ0zε+ρ0b2ε[b+2εr( d−b)b+εr( d−b)]]az and electric field E2 is ρ0b22ε0[1b+εr(d−b)]az.

Explanation of Solution

Calculation:

Differentiate the equation (16) with respect to z as,

dV1dz=−ρ0zε+ρ0b2ε[b+2εr(d−b)b+εr(d−b)]

Differentiate the equation (17) with respect to z as,

dV2dz=−ρ0b22ε0[1b+εr(d−b)]

The electric field intensity E1 is written as,

E1=−dV1dzaz ...... (18)

Here,

az is the plane along z axis.

Substitute −ρ0zε+ρ0b2ε[b+2εr(d−b)b+εr(d−b)] for dV1dz in equation (18).

E1=−[− ρ 0zε+ ρ 0b2ε[ b+2 ε r ( d−b ) b+ ε r ( d−b )]]az=[ ρ 0zε+ ρ 0b2ε[ b+2 ε r ( d−b ) b+ ε r ( d−b )]]az

The electric field intensity E2 is written as,

E2=−dV2dzaz ...... (19)

Substitute −ρ0b22ε0[1b+εr(d−b)] for dV2dz in equation (19).

E2=−[− ρ 0 b 22 ε 0[1 b+ ε r ( d−b )]]az=ρ0b22ε0[1b+ ε r( d−b)]az

Conclusion:

Therefore, the electric field E1 is [ρ0zε+ρ0b2ε[b+2εr( d−b)b+εr( d−b)]]az and electric field E2 is ρ0b22ε0[1b+εr(d−b)]az.

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Answer 4

Question

Chapter 6, Problem 6.34P

To determine

(a)

The voltage V.

Expert Solution

Answer to Problem 6.34P

The final voltages are:

V1=−ρ0z22ε+ρ0bz2ε[b+2εr(d−b)b+εr(d−b)] and V2=ρ0bε0(d−z)−ρ0b2ε0[b+2εr(d−b)b+εr(d−b)](d−z).

Explanation of Solution

Calculation:

The Poisson's equation is defined for z<b boundary condition (where b is the radius of conductor).

The Poisson's equation is written as,

d2V1dz2=−ρ0ε ...... (1)

Here,

ρ0 is the charge density.

ε is the permittivity.

z is the direction along z axis.

V1 is the voltage for case z<b.

Integrate the equation (1) with respect to z.

dV1dz=−ρ0zε+C1 ...... (2)

The Laplace's equation is written as,

d2V2dz2=0 ...... (3)

Integrate the equation (3) with respect to z.

dV2dz=C1′ ...... (4)

Substitute z=b in equation (2).

dV1dz=−ρ0bε+C1 ...... (5)

Simplified the equation (5) as,

εdV1dz=−ρ0b+εC1 ...... (6)

Equation (3) is multiplied with ε0 on both side as,

ε0dV2dz=ε0C1′ ...... (7)

If equation (6) and equation (7) is equal, then it is written as,

−ρ0b+εC1=ε0C1′ ..... (8)

Simplified the equation (8) as,

C1′=−ρ0bε0+εC1ε0

Substitute −ρ0bε0+εC1ε0 for C1′ in equation (4).

dV2dz=−ρ0bε0+εC1ε0 ..... (9)

Integrate the equation (2) with respect to z as,

V1=−ρ0z22ε+C1z+C2 ...... (10)

Integrate the equation (9) with respect to z as,

V2=−ρ0bzε0+εC1zε0+C2′ ..... (11)

Substitute d for z and 0 for V2 in equation (11).

0=−ρ0bdε0+εC1dε0+C2′ ..... (12)

Equation (12) is simplified as,

C2′=ρ0bdε0−εC1dε0

Substitute 0 for C2 in equation (10).

V1=−ρ0z22ε+C1z ...... (13)

Substitute ρ0bdε0−εC1dε0 for C2′ in equation (11).

V2=−ρ0bzε0+εC1zε0+ρ0bdε0−εC1dε0=ρ0bε0(d−z)−εC1ε0(d−z) ...... (14)

If equation (13) and equation (14) is equal, then it is written as,

−ρ0z22ε+C1z=ρ0bε0(d−z)−εC1ε0(d−z) ..... (15)

Substitute b for z and εεr for ε0 in equation (15).

C1=ρ0b2ε[b+2εr(d−b)b+εr(d−b)]

Substitute ρ0b2ε[b+2εr(d−b)b+εr(d−b)] for C1 in equation (13)

V1=−ρ0z22ε+ρ0bz2ε[b+2εr(d−b)b+εr(d−b)] ...... (16)

Substitute ρ0b2ε[b+2εr(d−b)b+εr(d−b)] for C1 in equation (14)

V2=ρ0bε0(d−z)−ρ0b2ε0[b+2εr(d−b)b+εr(d−b)](d−z) ...... (17)

Conclusion:

Therefore, the final voltages are V1=−ρ0z22ε+ρ0bz2ε[b+2εr(d−b)b+εr(d−b)] and V2=ρ0bε0(d−z)−ρ0b2ε0[b+2εr(d−b)b+εr(d−b)](d−z).

To determine

(b)

The electric field intensity.

Expert Solution

Answer to Problem 6.34P

The electric field E1 is [ρ0zε+ρ0b2ε[b+2εr( d−b)b+εr( d−b)]]az and electric field E2 is ρ0b22ε0[1b+εr(d−b)]az.

Explanation of Solution

Calculation:

Differentiate the equation (16) with respect to z as,

dV1dz=−ρ0zε+ρ0b2ε[b+2εr(d−b)b+εr(d−b)]

Differentiate the equation (17) with respect to z as,

dV2dz=−ρ0b22ε0[1b+εr(d−b)]

The electric field intensity E1 is written as,

E1=−dV1dzaz ...... (18)

Here,

az is the plane along z axis.

Substitute −ρ0zε+ρ0b2ε[b+2εr(d−b)b+εr(d−b)] for dV1dz in equation (18).

E1=−[− ρ 0zε+ ρ 0b2ε[ b+2 ε r ( d−b ) b+ ε r ( d−b )]]az=[ ρ 0zε+ ρ 0b2ε[ b+2 ε r ( d−b ) b+ ε r ( d−b )]]az

The electric field intensity E2 is written as,

E2=−dV2dzaz ...... (19)

Substitute −ρ0b22ε0[1b+εr(d−b)] for dV2dz in equation (19).

E2=−[− ρ 0 b 22 ε 0[1 b+ ε r ( d−b )]]az=ρ0b22ε0[1b+ ε r( d−b)]az

Conclusion:

Therefore, the electric field E1 is [ρ0zε+ρ0b2ε[b+2εr( d−b)b+εr( d−b)]]az and electric field E2 is ρ0b22ε0[1b+εr(d−b)]az.

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Answer 5

Chapter 6, Problem 6.34P

To determine

(a)

The voltage V.

Expert Solution

Answer to Problem 6.34P

The final voltages are:

V1=−ρ0z22ε+ρ0bz2ε[b+2εr(d−b)b+εr(d−b)] and V2=ρ0bε0(d−z)−ρ0b2ε0[b+2εr(d−b)b+εr(d−b)](d−z).

Explanation of Solution

Calculation:

The Poisson's equation is defined for z<b boundary condition (where b is the radius of conductor).

The Poisson's equation is written as,

d2V1dz2=−ρ0ε ...... (1)

Here,

ρ0 is the charge density.

ε is the permittivity.

z is the direction along z axis.

V1 is the voltage for case z<b.

Integrate the equation (1) with respect to z.

dV1dz=−ρ0zε+C1 ...... (2)

The Laplace's equation is written as,

d2V2dz2=0 ...... (3)

Integrate the equation (3) with respect to z.

dV2dz=C1′ ...... (4)

Substitute z=b in equation (2).

dV1dz=−ρ0bε+C1 ...... (5)

Simplified the equation (5) as,

εdV1dz=−ρ0b+εC1 ...... (6)

Equation (3) is multiplied with ε0 on both side as,

ε0dV2dz=ε0C1′ ...... (7)

If equation (6) and equation (7) is equal, then it is written as,

−ρ0b+εC1=ε0C1′ ..... (8)

Simplified the equation (8) as,

C1′=−ρ0bε0+εC1ε0

Substitute −ρ0bε0+εC1ε0 for C1′ in equation (4).

dV2dz=−ρ0bε0+εC1ε0 ..... (9)

Integrate the equation (2) with respect to z as,

V1=−ρ0z22ε+C1z+C2 ...... (10)

Integrate the equation (9) with respect to z as,

V2=−ρ0bzε0+εC1zε0+C2′ ..... (11)

Substitute d for z and 0 for V2 in equation (11).

0=−ρ0bdε0+εC1dε0+C2′ ..... (12)

Equation (12) is simplified as,

C2′=ρ0bdε0−εC1dε0

Substitute 0 for C2 in equation (10).

V1=−ρ0z22ε+C1z ...... (13)

Substitute ρ0bdε0−εC1dε0 for C2′ in equation (11).

V2=−ρ0bzε0+εC1zε0+ρ0bdε0−εC1dε0=ρ0bε0(d−z)−εC1ε0(d−z) ...... (14)

If equation (13) and equation (14) is equal, then it is written as,

−ρ0z22ε+C1z=ρ0bε0(d−z)−εC1ε0(d−z) ..... (15)

Substitute b for z and εεr for ε0 in equation (15).

C1=ρ0b2ε[b+2εr(d−b)b+εr(d−b)]

Substitute ρ0b2ε[b+2εr(d−b)b+εr(d−b)] for C1 in equation (13)

V1=−ρ0z22ε+ρ0bz2ε[b+2εr(d−b)b+εr(d−b)] ...... (16)

Substitute ρ0b2ε[b+2εr(d−b)b+εr(d−b)] for C1 in equation (14)

V2=ρ0bε0(d−z)−ρ0b2ε0[b+2εr(d−b)b+εr(d−b)](d−z) ...... (17)

Conclusion:

Therefore, the final voltages are V1=−ρ0z22ε+ρ0bz2ε[b+2εr(d−b)b+εr(d−b)] and V2=ρ0bε0(d−z)−ρ0b2ε0[b+2εr(d−b)b+εr(d−b)](d−z).

To determine

(b)

The electric field intensity.

Expert Solution

Answer to Problem 6.34P

The electric field E1 is [ρ0zε+ρ0b2ε[b+2εr( d−b)b+εr( d−b)]]az and electric field E2 is ρ0b22ε0[1b+εr(d−b)]az.

Explanation of Solution

Calculation:

Differentiate the equation (16) with respect to z as,

dV1dz=−ρ0zε+ρ0b2ε[b+2εr(d−b)b+εr(d−b)]

Differentiate the equation (17) with respect to z as,

dV2dz=−ρ0b22ε0[1b+εr(d−b)]

The electric field intensity E1 is written as,

E1=−dV1dzaz ...... (18)

Here,

az is the plane along z axis.

Substitute −ρ0zε+ρ0b2ε[b+2εr(d−b)b+εr(d−b)] for dV1dz in equation (18).

E1=−[− ρ 0zε+ ρ 0b2ε[ b+2 ε r ( d−b ) b+ ε r ( d−b )]]az=[ ρ 0zε+ ρ 0b2ε[ b+2 ε r ( d−b ) b+ ε r ( d−b )]]az

The electric field intensity E2 is written as,

E2=−dV2dzaz ...... (19)

Substitute −ρ0b22ε0[1b+εr(d−b)] for dV2dz in equation (19).

E2=−[− ρ 0 b 22 ε 0[1 b+ ε r ( d−b )]]az=ρ0b22ε0[1b+ ε r( d−b)]az

Conclusion:

Therefore, the electric field E1 is [ρ0zε+ρ0b2ε[b+2εr( d−b)b+εr( d−b)]]az and electric field E2 is ρ0b22ε0[1b+εr(d−b)]az.

Answer 6

Chapter 6, Problem 6.34P

To determine

(a)

The voltage V.

Expert Solution

Answer to Problem 6.34P

The final voltages are:

V1=−ρ0z22ε+ρ0bz2ε[b+2εr(d−b)b+εr(d−b)] and V2=ρ0bε0(d−z)−ρ0b2ε0[b+2εr(d−b)b+εr(d−b)](d−z).

Explanation of Solution

Calculation:

The Poisson's equation is defined for z<b boundary condition (where b is the radius of conductor).

The Poisson's equation is written as,

d2V1dz2=−ρ0ε ...... (1)

Here,

ρ0 is the charge density.

ε is the permittivity.

z is the direction along z axis.

V1 is the voltage for case z<b.

Integrate the equation (1) with respect to z.

dV1dz=−ρ0zε+C1 ...... (2)

The Laplace's equation is written as,

d2V2dz2=0 ...... (3)

Integrate the equation (3) with respect to z.

dV2dz=C1′ ...... (4)

Substitute z=b in equation (2).

dV1dz=−ρ0bε+C1 ...... (5)

Simplified the equation (5) as,

εdV1dz=−ρ0b+εC1 ...... (6)

Equation (3) is multiplied with ε0 on both side as,

ε0dV2dz=ε0C1′ ...... (7)

If equation (6) and equation (7) is equal, then it is written as,

−ρ0b+εC1=ε0C1′ ..... (8)

Simplified the equation (8) as,

C1′=−ρ0bε0+εC1ε0

Substitute −ρ0bε0+εC1ε0 for C1′ in equation (4).

dV2dz=−ρ0bε0+εC1ε0 ..... (9)

Integrate the equation (2) with respect to z as,

V1=−ρ0z22ε+C1z+C2 ...... (10)

Integrate the equation (9) with respect to z as,

V2=−ρ0bzε0+εC1zε0+C2′ ..... (11)

Substitute d for z and 0 for V2 in equation (11).

0=−ρ0bdε0+εC1dε0+C2′ ..... (12)

Equation (12) is simplified as,

C2′=ρ0bdε0−εC1dε0

Substitute 0 for C2 in equation (10).

V1=−ρ0z22ε+C1z ...... (13)

Substitute ρ0bdε0−εC1dε0 for C2′ in equation (11).

V2=−ρ0bzε0+εC1zε0+ρ0bdε0−εC1dε0=ρ0bε0(d−z)−εC1ε0(d−z) ...... (14)

If equation (13) and equation (14) is equal, then it is written as,

−ρ0z22ε+C1z=ρ0bε0(d−z)−εC1ε0(d−z) ..... (15)

Substitute b for z and εεr for ε0 in equation (15).

C1=ρ0b2ε[b+2εr(d−b)b+εr(d−b)]

Substitute ρ0b2ε[b+2εr(d−b)b+εr(d−b)] for C1 in equation (13)

V1=−ρ0z22ε+ρ0bz2ε[b+2εr(d−b)b+εr(d−b)] ...... (16)

Substitute ρ0b2ε[b+2εr(d−b)b+εr(d−b)] for C1 in equation (14)

V2=ρ0bε0(d−z)−ρ0b2ε0[b+2εr(d−b)b+εr(d−b)](d−z) ...... (17)

Conclusion:

Therefore, the final voltages are V1=−ρ0z22ε+ρ0bz2ε[b+2εr(d−b)b+εr(d−b)] and V2=ρ0bε0(d−z)−ρ0b2ε0[b+2εr(d−b)b+εr(d−b)](d−z).

Answer 7

Chapter 6, Problem 6.34P

To determine

(a)

The voltage V.

Answer 8

Expert Solution

Answer to Problem 6.34P

The final voltages are:

V1=−ρ0z22ε+ρ0bz2ε[b+2εr(d−b)b+εr(d−b)] and V2=ρ0bε0(d−z)−ρ0b2ε0[b+2εr(d−b)b+εr(d−b)](d−z).

Answer 9

Expert Solution

Answer 10

Expert Solution

Answer 11

Expert Solution

Answer 12

Explanation of Solution

Calculation:

The Poisson's equation is defined for z<b boundary condition (where b is the radius of conductor).

The Poisson's equation is written as,

d2V1dz2=−ρ0ε ...... (1)

Here,

ρ0 is the charge density.

ε is the permittivity.

z is the direction along z axis.

V1 is the voltage for case z<b.

Integrate the equation (1) with respect to z.

dV1dz=−ρ0zε+C1 ...... (2)

The Laplace's equation is written as,

d2V2dz2=0 ...... (3)

Integrate the equation (3) with respect to z.

dV2dz=C1′ ...... (4)

Substitute z=b in equation (2).

dV1dz=−ρ0bε+C1 ...... (5)

Simplified the equation (5) as,

εdV1dz=−ρ0b+εC1 ...... (6)

Equation (3) is multiplied with ε0 on both side as,

ε0dV2dz=ε0C1′ ...... (7)

If equation (6) and equation (7) is equal, then it is written as,

−ρ0b+εC1=ε0C1′ ..... (8)

Simplified the equation (8) as,

C1′=−ρ0bε0+εC1ε0

Substitute −ρ0bε0+εC1ε0 for C1′ in equation (4).

dV2dz=−ρ0bε0+εC1ε0 ..... (9)

Integrate the equation (2) with respect to z as,

V1=−ρ0z22ε+C1z+C2 ...... (10)

Integrate the equation (9) with respect to z as,

V2=−ρ0bzε0+εC1zε0+C2′ ..... (11)

Substitute d for z and 0 for V2 in equation (11).

0=−ρ0bdε0+εC1dε0+C2′ ..... (12)

Equation (12) is simplified as,

C2′=ρ0bdε0−εC1dε0

Substitute 0 for C2 in equation (10).

V1=−ρ0z22ε+C1z ...... (13)

Substitute ρ0bdε0−εC1dε0 for C2′ in equation (11).

V2=−ρ0bzε0+εC1zε0+ρ0bdε0−εC1dε0=ρ0bε0(d−z)−εC1ε0(d−z) ...... (14)

If equation (13) and equation (14) is equal, then it is written as,

−ρ0z22ε+C1z=ρ0bε0(d−z)−εC1ε0(d−z) ..... (15)

Substitute b for z and εεr for ε0 in equation (15).

C1=ρ0b2ε[b+2εr(d−b)b+εr(d−b)]

Substitute ρ0b2ε[b+2εr(d−b)b+εr(d−b)] for C1 in equation (13)

V1=−ρ0z22ε+ρ0bz2ε[b+2εr(d−b)b+εr(d−b)] ...... (16)

Substitute ρ0b2ε[b+2εr(d−b)b+εr(d−b)] for C1 in equation (14)

V2=ρ0bε0(d−z)−ρ0b2ε0[b+2εr(d−b)b+εr(d−b)](d−z) ...... (17)

Conclusion:

Therefore, the final voltages are V1=−ρ0z22ε+ρ0bz2ε[b+2εr(d−b)b+εr(d−b)] and V2=ρ0bε0(d−z)−ρ0b2ε0[b+2εr(d−b)b+εr(d−b)](d−z).

Answer 13

To determine

(b)

The electric field intensity.

Expert Solution

Answer to Problem 6.34P

The electric field E1 is [ρ0zε+ρ0b2ε[b+2εr( d−b)b+εr( d−b)]]az and electric field E2 is ρ0b22ε0[1b+εr(d−b)]az.

Explanation of Solution

Calculation:

Differentiate the equation (16) with respect to z as,

dV1dz=−ρ0zε+ρ0b2ε[b+2εr(d−b)b+εr(d−b)]

Differentiate the equation (17) with respect to z as,

dV2dz=−ρ0b22ε0[1b+εr(d−b)]

The electric field intensity E1 is written as,

E1=−dV1dzaz ...... (18)

Here,

az is the plane along z axis.

Substitute −ρ0zε+ρ0b2ε[b+2εr(d−b)b+εr(d−b)] for dV1dz in equation (18).

E1=−[− ρ 0zε+ ρ 0b2ε[ b+2 ε r ( d−b ) b+ ε r ( d−b )]]az=[ ρ 0zε+ ρ 0b2ε[ b+2 ε r ( d−b ) b+ ε r ( d−b )]]az

The electric field intensity E2 is written as,

E2=−dV2dzaz ...... (19)

Substitute −ρ0b22ε0[1b+εr(d−b)] for dV2dz in equation (19).

E2=−[− ρ 0 b 22 ε 0[1 b+ ε r ( d−b )]]az=ρ0b22ε0[1b+ ε r( d−b)]az

Conclusion:

Therefore, the electric field E1 is [ρ0zε+ρ0b2ε[b+2εr( d−b)b+εr( d−b)]]az and electric field E2 is ρ0b22ε0[1b+εr(d−b)]az.

Answer 14

To determine

(b)

The electric field intensity.

Answer 15

Expert Solution

Answer to Problem 6.34P

The electric field E1 is [ρ0zε+ρ0b2ε[b+2εr( d−b)b+εr( d−b)]]az and electric field E2 is ρ0b22ε0[1b+εr(d−b)]az.

Answer 16

Expert Solution

Answer 17

Expert Solution

Answer 18

Expert Solution

Answer 19

Explanation of Solution

Calculation:

Differentiate the equation (16) with respect to z as,

dV1dz=−ρ0zε+ρ0b2ε[b+2εr(d−b)b+εr(d−b)]

Differentiate the equation (17) with respect to z as,

dV2dz=−ρ0b22ε0[1b+εr(d−b)]

The electric field intensity E1 is written as,

E1=−dV1dzaz ...... (18)

Here,

az is the plane along z axis.

Substitute −ρ0zε+ρ0b2ε[b+2εr(d−b)b+εr(d−b)] for dV1dz in equation (18).

E1=−[− ρ 0zε+ ρ 0b2ε[ b+2 ε r ( d−b ) b+ ε r ( d−b )]]az=[ ρ 0zε+ ρ 0b2ε[ b+2 ε r ( d−b ) b+ ε r ( d−b )]]az

The electric field intensity E2 is written as,

E2=−dV2dzaz ...... (19)

Substitute −ρ0b22ε0[1b+εr(d−b)] for dV2dz in equation (19).

E2=−[− ρ 0 b 22 ε 0[1 b+ ε r ( d−b )]]az=ρ0b22ε0[1b+ ε r( d−b)]az

Conclusion:

Therefore, the electric field E1 is [ρ0zε+ρ0b2ε[b+2εr( d−b)b+εr( d−b)]]az and electric field E2 is ρ0b22ε0[1b+εr(d−b)]az.

Answer 20

Ch. 6 - Prob. 6.1P Ch. 6 - Let S = 100 mm2. d= 3 mm, and er = 12 for a...Ch. 6 - Capacitors tend to be more expensive as their...Ch. 6 - Prob. 6.4P Ch. 6 - Prob. 6.5P Ch. 6 - A parallel-plane capacitor is made using two...Ch. 6 - For the capacitor of Problem 6.6, consider the...Ch. 6 - Prob. 6.8P Ch. 6 - Prob. 6.9P Ch. 6 - A coaxial cable has conductor dimensions of a =...

(a) The voltage V .

Concept explainers

(a)

The voltage V.

Answer to Problem 6.34P

Explanation of Solution

(b)

The electric field intensity.

Answer to Problem 6.34P

Explanation of Solution

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Chapter 6 Solutions

(a) The voltage V .

Concept explainers

(a) The voltage V.

Answer to Problem 6.34P

Explanation of Solution

(b) The electric field intensity.

Answer to Problem 6.34P

Explanation of Solution

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Chapter 6 Solutions

(a)

The voltage V.

(b)

The electric field intensity.