Physics for Scientists and Engineers: Foundations and Connections
Physics for Scientists and Engineers: Foundations and Connections
1st Edition
ISBN: 9781133939146
Author: Katz, Debora M.
Publisher: Cengage Learning
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Chapter 26, Problem 55PQ

The electric potential is given by V = 4x2z + 2xy2 − 8yz2 in a region of space, with x, y, and z in meters and V in volts.

  1. a. What are the x, y, and z components of the electric field in this region?
  2. b. What is the magnitude of the electric field at the coordinates (2.00 m, −2.00 m, 1.00 m)?

(a)

Expert Solution
Check Mark
To determine

The x, y and z components of electric field in the region.

Answer to Problem 55PQ

The electric field in the regionis E=(8xz+2y2)i^(4xy8z2)j^(4x216yz)k^.

Explanation of Solution

Write the equation for the electric field.

    E=Exi^+Eyj^+Ezk^                                                                                          (I)

Here, Ex is the x component of the electric field, Ey is the y component of the electric field and Ez is the z component of the electric field.

Write the equation for the the x component of the electric field.

    Ex=Vx                                                                                                         (II)

Here, Ex is the electric field along x axis and V/x is the partial derivative of the potential gradient along x axis.

Write the equation for the the y component of the electric field.

    Ey=Vy                                                                                                        (III)

Here, Ey is the electric field along y axis and V/y is the partial derivative of the potential gradient along y axis.

Write the equation for the the z component of the electric field.

    Ez=Vz                                                                                                        (IV)

Here, Ez is the electric field along z axis and V/z is the partial derivative of the potential gradient along z axis.

Conclusion:

Substitute 4x2z+2xy28yz2 for V in equation (II) to find Ex.

    Ex=(4x2z+2xy28yz2)x=(8xz+2y2)

Substitute 4x2z+2xy28yz2 for V in equation (III) to find Ey.

    Ey=(4x2z+2xy28yz2)y=(4xzy8yz2)

Substitute 4x2z+2xy28yz2 for V in equation (IV) to find Ez.

    Ez=(4x2z+2xy28yz2)z=(4x216yz)

Thus, from equation (I), write the electric field.

    E=(8xz+2y2)i^(4xy8z2)j^(4x216yz)k^

Thus, the electric field in the region is E=(8xz+2y2)i^(4xy8z2)j^(4x216yz)k^.

(b)

Expert Solution
Check Mark
To determine

The magnitude of the electric field.

Answer to Problem 55PQ

The magnitude of the electric field is 58.8V/m.

Explanation of Solution

Write the equation for the the x component of the electric field.

    Ex=(8xz+2y2)                                                                                          (V)

Write the equation for the the y component of the electric field.

    Ey=(4xzy8yz2)                                                                                     (VI)

Write the equation for the the z component of the electric field.

    Ez=(4x216yz)                                                                                       (VII)

Write the equation for the magnitude of the electric field.

    E=Ex2+Ey2+Ez2                                                                                      (VIII)

Here, E is the total magnitude of the electric field.

Conclusion:

Substitute 2.00m for x, 2.00m for y and 1.00m for z in equation (V) to find Ex.

    Ex=(8(2.00m)(1.00m)+2(2.00m)2)=24.0V/m

Substitute 2.00m for x, 2.00m for y and 1.00m for z in equation (VI) to find Ey.

    Ey=(4(2.00m)(1.00m)(2.00m)8(2.00m)(1.00m)2)=24.0V/m

Substitute 2.00m for x, 2.00m for y and 1.00m for z in equation (VII) to find Ez.

    Ez=(4(2.00m)216(2.00m)(1.00m))=48.0V/m

Substitute 24.0V/m for Ex, 24.0V/m for Ey and 48.0V/m for Ez in equation (VII) to find E.

    E=(24.0V/m)2+(24.0V/m)2+(48.0V/m)2=58.8V/m

Thus, the magnitude of the electric field is 58.8V/m.

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Chapter 26 Solutions

Physics for Scientists and Engineers: Foundations and Connections

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