Part ASuppose a disk with area A is placed in a uniformelectric field of magnitude E. The disk is oriented so thatthe vector normal to its surface, îñ, makes an angle 0with the electric field, as shown in the figure. (Figure 1)What is the electric flux PE through the surface ofthe disk that is facing right (the normal vector to thissurface is shown in the figure)? Assume that thepresence of the disk does not interfere with theelectric field.Express your answer in terms of E, A, and 0• View Available Hint(s)Figure1 of 1ФЕ

The electric flux can be found using the dot product of the electric field and area vector.

Part A Suppose a disk with area A is placed in a uniform electric field of magnitude E. The disk is oriented so that the vector normal to its surface, n, makes an angle 0 with the electric field, as shown in the figure. (Figure 1) What is the electric flux E through the surface of the disk that is facing right (the normal vector to this surface is shown in the figure)? Assume that the presence of the disk does not interfere with the electric field. Express your answer in terms of E, A, and 0 • View Available Hint(s) Figure 1 of 1 ΑΣφ

Part A Suppose a disk with area A is placed in a uniform electric field of magnitude E. The disk is oriented so that the vector normal to its surface, n, makes an angle 0 with the electric field, as shown in the figure. (Figure 1) What is the electric flux E through the surface of the disk that is facing right (the normal vector to this surface is shown in the figure)? Assume that the presence of the disk does not interfere with the electric field. Express your answer in terms of E, A, and 0 • View Available Hint(s) Figure 1 of 1 ΑΣφ

University Physics Volume 2

18th Edition

ISBN:9781938168161

Author:OpenStax

Publisher:OpenStax

Chapter6: Gauss's Law

Section: Chapter Questions

Problem 76AP: Suppose that the electric field of an isolated point charge were proportional to 1/r2+ rather than...

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