22. Figure P24.22 (page 742) represents the top view of a cubic gaussian surface in a...
The figure below represents the top view of a cubic surface in a uniform electric field oriented parallel to the top and bottom faces of the cube. The field makes an angle θ=40o with side and the area of each face is A . a) Draw an area vector A for each face, , , , b) Label the angle between the area vector A and the electric field vector E for each face. c) Find flux through each face....
and : No charur inside but there are charges outside the closed (TLC) Distinguishing between and : No producing an electric field. A cubie Gaussian surface with a side has two horizontal faces and is in a uniform electrie field of 30 N/C which is directed vertically upward. (1) Find the net electric flux through the cube. (Hint: If there are equal numbers of field lines going into and out of a CLOSED surface, the net flux through the surface...
2. An imaginary cubical surface of side L is in a region of uniform electric field E. Find the electric flux through each face of the cube and the total flux through the cube when (a) it is oriented with two of its faces perpendiculars to E(b) the cube is turned by an angle about the vertical axis. (a) ol HA 190 - 0 S
Cubic Box Points:2 A cubic box of side a H0.420 m is placed so that its edges are parallel to the coordinate axes, as shown in the figure. There is NO net electric charge inside the box, but the space in and around the box is filled with a nonuniform electric field of the following form: E(x,y,z) Kz j + Ky k, where K = 4.40 N/(Cm) is a constant. What is the electric flux through the top face of...
An electric field given by E→ = 4.4î - 7.4(y2 + 1.6)ĵ pierces the Gaussian cube of edge length 0.320 m and positioned as shown in the figure. (The magnitude E is in newtons per coulomb and the position x is in meters.) What is the electric flux through the (a) top face, (b) bottom face, (c) left face, and (d) back face? (e) What is the net electric flux through the cube?
For the situation in problem 23.2, find the flux (in Nm2/C) through the y = a (right) face of the cube of side a = 2.2 musing an electric field with components in N/C of Ex = 4.0, Ey = -2.0(x/a - 3.0), and Ez = 0. (2 sig. figs.) through the surface. 2 An electric field given by E 4.0i- 3.0(y2 + 2.0)i pierces a Gaussian cube of edge length 2.0 m and positioned as shown in Fig. 23-7....
rge density p must a region of space Explain. olume charge den pe uniform in this n of uniform posi- Can E be uniform 22.6 . The cube in Fig. E22.6 has sides of length L = 10.0 cm. The electric field is uniform, has magnitude E = 4.00 X 10N/C, and is parallel to the xy-plane at an angle of 53.Iº measured from the +x-axis toward the +y-axis. (a) What is the electric flux through each of the six...
An electric field given by E→ = 5.2 î - 9.5(y2 + 5.8) ĵ pierces the Gaussian cube of edge length 0.980 m and positioned as shown in the figure. (The magnitude E is in newtons per coulomb and the position x is in meters.) What is the electric flux through the (a) top face, (b) bottom face, (c) left face, and (d) back face? (e) What is the net electric flux through the cube? Gaussian surface
At each point on the surface of the cube shown in the figure the electric field is parallel to the z axis. The length of each edge of the cube is 4.2 m. On the top face of the cute the electric field E =-39k N/C and on the bottom face it is E = + 25k N/C . Determine the net charge contained within the cube. Units I N/C or V/m 14
At each point on the surface of the cube shown in the figure, the electric field is parallel to the z axis. The length of each edge of the cube is 4.0 m. On the top face of the cube E with arrow = −33 k N/C, and on the bottom face of the cube E with arrow = +14 k N/C. Determine the net charge contained within the cube. ?? C