A cube has edge length 166. cm and is oriented in a region of uniform electric...

In the case of a uniform electric field and a flat surface, the electric flux is...

In the case of a uniform electric field and a flat surface, the electric flux is defined as the dot product of the electric field and the area, where the direction of the area is the normal to the area pointing out of a closed region. Consider a cube that measures 4.0 m on edge. The edges lie along the coordinate axes x, y, and z, with one corner at the origin, and the other corners having positive coordinates. A...

The cube in fig. E22.6 has sides of length L=10.0cm. The electric field is uniform, has...

The cube in fig. E22.6 has sides of length L=10.0cm. The electric field is uniform, has magnitude E=4.00(10^3) N/C, and is parallel to the xy-plane at an angle of 53.1 degrees measured from the +x axis toward the +y-axis. (a) What is the electric flux through each of the six cube faces S1, S2, S3, S4, S5, and S6? (b) What is the total electric flux through all faces of the cube?

The direction of a uniform electric field is in the y–z plane at an angle of...

The direction of a uniform electric field is in the y–z plane at an angle of 30 degrees from the +y axis, 60 degrees from the +z axis. This uniform field extends throughout the region of a 2.0-m cube similar to the one in Fig. 24.7. What is the electric flux through each of the faces of the cube, labeled 1 through 6 in Fig. 24.7b? What is the net flux?

The figure shows a Gaussian surface in the shape of a cube with edge length 2.00...

The figure shows a Gaussian surface in the shape of a cube with edge length 2.00 m. What are (a) the net flux through the surface and (b) the net charge qenc enclosed by the surface if the electric field in the region is in the positive y direction and has a magnitude that is given by E = 2.71y N/C? What are (c) the net flux and (d) net enclosed charge if the electric field is in the xy...

The figure shows a Gaussian surface in the shape of a cube with edge length 1.30...

The figure shows a Gaussian surface in the shape of a cube with edge length 1.30 m. What are (a) the net flux through the surface and (b) the net charge qenc enclosed by the surface if the electric field in the region is in the positive y direction and has a magnitude that is given by E = 3.58y N/C? What are (c) the net flux and (d) net enclosed charge if the electric field is in the xy...

A cube on the XY plane has an edge length of ''a''. When we take the...

A cube on the XY plane has an edge length of ''a''. When we take the starting point as the bottom left corner of the cube; under the uneven electric field given as E= 2x i + 5y j a) What is the electric flux passing through the right face of the cube (x=a plane) b) What is the net charge that has left inside the cube

In a region of space there is an electric field E⃗  that is in the z-direction and...

In a region of space there is an electric field E⃗  that is in the z-direction and that has magnitude E=(836N/(C⋅m))x. Find the flux for this field through a square in the xy-plane at z = 0 and with side length 0.510 m . One side of the square is along the +x -axis and another side is along the +y-axis.

A charge of 170 µC is at the center of a cube of edge 50.0 cm....

A charge of 170 µC is at the center of a cube of edge 50.0 cm. (a) Find the total flux through each face of the cube. (b) Find the flux through the whole surface of the cube. c) Would your answers to parts (a) or (b) change if the charge were not at the center? (Select all that apply.) (a) would change(b) would changeneither would change

A uniform electric field is given (in units of N/C) by E = 63 i –...

A uniform electric field is given (in units of N/C) by E = 63 i – 87 j + 48 k , where i, j, k are unit vectors in the directions of x, y, z axes respectively. Find the magnitude of the electric flux through a circle of a 15 cm cm radius located in the xz-plane

a) There is a uniform electric flux perpendicular to a circular region of radius R =...

a) There is a uniform electric flux perpendicular to a circular region of radius R = 2.8 cm. The electric flux is only contained within the circular region, and the total value can be expressed by the following function: ΦE = 6.3t, where ΦE is in V⋅m when t is in seconds. At a radial distance of 4.9 cm from the center of the circle, what is the magnitude of the induced magnetic field? Express your answer in fT (femtoteslas)....