EBK WEBASSIGN FOR KATZ'S PHYSICS FOR SC
EBK WEBASSIGN FOR KATZ'S PHYSICS FOR SC
1st Edition
ISBN: 9781337684651
Author: Katz
Publisher: VST
Question
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Chapter 31, Problem 27PQ

(a)

To determine

Find the expression for magnitudes of the magnetic field in each of the four layers.

(a)

Expert Solution
Check Mark

Answer to Problem 27PQ

The expression for magnitudes of the magnetic field in each of the four layers are μ0Ir2πr12_ for B1, μ0I2πr_ for B2, μ0I2πr(r2r22)(r32r22)_ for B3 and 0_ for B4.

Explanation of Solution

Write the expression for Ampere’s Law for the area bounded by the curve as.

    B.dl=μ0Ithru

Rearrange above equation for B

  B=μ0Ithrudl                                                                                                   (I)

Here, B is magnetic field, dl is length of element, Ithru is current through loop and μ0 is permeability of free space.

Write the expression for current density as.

    J=IA                                                                                                        (II)

Here, J is current density, I is the current and A is area.

Write the expression for area of the circle as.

    A=πR2

Substitute πR2 for A in equation (II).

    J=IπR2

Consider that the inner coaxial cable of radius r1 and r be the Amperian loop of radius. The current in the loop is product of current density and area of the loop.

Write the expression for Amperian loop current as.

    Ithru=JA1                                                                                                  (III)

Substitute Iπr12 for J and πr2 for A1 in equation (III)

    Ithru=Ir2r12

Write the expression for Amperian loop is the circumferences of the circle as.

    dl=2πr

Substitute 2πr for dl and Ir2r12 for Ithru in equation (I).

    B1(2πr)=μ0(Ir2r12)

Rearrange the above equation as.

    B1=μ0Ir2πr12                                                                                                (IV)

Thus, the magnitude of the magnetic field in inner layer r1 is μ0Ir2πr12_.

Consider the inside insulator coaxial r be the Amperian loop of radius. In this case, the magnetic field due to inner solenoid is zero. Because the region is outside of the inner solenoid, the magnetic field contribution is due to the outer solenoid.

The current in the loop is product of current density and area of loop is Ithru=I.

The length of Ameprian loop is equal to the circumferences of the circle that is dl=2πr.

Substitute 2πr for dl and I for Ithru in equation (I).

    B2=μ0I2πr                                                                                                   (V)

Thus, the magnitude of the magnetic field in inside insulator layer is μ0I2πr_.

Consider the outer coaxial of radius r3, area of the outer loop is A3=π(r32r22) and r be the radius of Amperian loop. Area of the Amperian loop is Ar=π(r2r22).

Write the current density of the layer r3 as.

    J=IA3                                                                                                     (VI)

Substitute π(r32r22) for A3 in equation (VI)

    J=Iπ(r32r22)

Write the expression for Amperian loop current as.

    Ithru=JAr                                                                                                (VII)

Substitute π(r2r22) for Ar and Iπ(r32r22) for J in equation (VII).

    Ithru=I(r2r22)(r32r22)

Substitute 2πr for dl and I(r2r22)(r32r22) for Ithru in equation (I).

    B3=μ0I2πr(r2r22)(r32r22)                                                                                (VIII)

Here,B3 is magnetic field in third layer, I is current, r is radius of Gaussian surface, r2 is radius of second layer and r3 is radius for third layer.

Thus, the magnetic field on the third layer is μ0I2πr(r2r22)(r32r22)_.

Write the expression for net magnetic field at the layer r3 is separation between the inside insulator layer field and layer r1 field as.

    Bnet=B2B3                                                                                            (IX)

Substitute μ0I2πr for B2 and μ0I2πr(r2r22)(r32r22) for B3 in equation (IX)

    Bnet=μ0I2πr[1(r2r22)(r32r22)]                                                                          (X)

The net current enclosed inside the coaxial cable is zero.

Thus, the magnitude of the magnetic field outside the insulator layer is zero that is B4=0_.

Conclusion:

Thus, the expression for magnitudes of the magnetic field in each of the four layers are μ0Ir2πr12_ for B1, μ0I2πr_ for B2, μ0I2πr(r2r22)(r32r22)_ for B3 and 0_ for B4.

(b)

To determine

Compare the part a results with the magnetic field produced by a long, straight wire and explain the advantage of using a coax.

(b)

Expert Solution
Check Mark

Answer to Problem 27PQ

The expression for magnitude of the magnetic field for long straight current carrying wire is equal to the magnitude of the magnetic field in inside insulator layer.

Explanation of Solution

Write the expression for the magnetic field strength (magnitude) produced by a long straight current-carrying wire as.

    B=μ0I2πr

The expression for long straight current carrying wire is equal to the magnitude of the magnetic field in inside insulator layer.

The advantage of using of coaxial cable as:

  1. 1. The inner conductor is in a Faraday shield, noise immunity is improved, and coax has lower error rates and therefore slightly better performance than twisted-pair.
  2. 2. Coax provides sufficient frequency range to support multiple channel, which allows for much greater throughput.
  3. 3. It also provides greater spacing between amplifiers coax's cable shielding reduces noise and crosstalk

Conclusion:

Thus, the expression for magnitude of the magnetic field for long straight current carrying wire is equal to the magnitude of the magnetic field in inside insulator layer.

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Chapter 31 Solutions

EBK WEBASSIGN FOR KATZ'S PHYSICS FOR SC

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