Consider eight charges q, placed on each corner of a cube of side length s. Show...

Eight point charges, each of magnitude q, are located on the corners of a cube of...

Eight point charges, each of magnitude q, are located on the corners of a cube of edge s, as shown in Fig. 3 (i) Determine the x, y, and z components of the resultant force exerted by the other charges on the charge located at point A. (ii) What are the magnitude and direction of this resultant force? (iii) Show that the magnitude of the electric field at the center of any face of the cube has a value of...

A cube with a side length of 2 meters was placed at the origin point (Center...

A cube with a side length of 2 meters was placed at the origin point (Center of the cube at the origin). There is also a point load at the 8 corners of the cube. Q, which is the value of point loads, is equal to the sum of the coordinate values of that point. (Q = x + y + z) a) Find the electric field and coulomb potential at the origin and at any point in space. b)...

(8 point charges on a cube) A cube of edge a carries a point charge q...

(8 point charges on a cube) A cube of edge a carries a point charge q at each corner. (a) Show that the magnitude of the resultant force on any one of the charges is F = 3.29kq2/a2. (b) What is the direction of F? relative to the cube edges?

A charge Q is placed at the center of a square of side 4cm; each corner...

A charge Q is placed at the center of a square of side 4cm; each corner of the square has a fixed charge of 1.00 ?C. If the resulting force acting on each charge is zero, the charge Q is

(a) For a square of side 2.000 cm with charges of +8.000 µC at each corner,...

(a) For a square of side 2.000 cm with charges of +8.000 µC at each corner, find the electric field at the center of the square. N/C (b) Find the potential at the center. × 10 V

Consider a square which is 1.0 m on a side. Charges are placed at the corners...

Consider a square which is 1.0 m on a side. Charges are placed at the corners of the square as follows: +4.0 μC at (0, 0); +4.0 μC at (1, 1); +3.0 μC at (1, 0); -3.0 μC at (0, 1). What is the magnitude of the electric field at the square's center?

Consider a square of side r = 4.60 cm with two q = +9.00 μC charges...

Consider a square of side r = 4.60 cm with two q = +9.00 μC charges at adjacent corners of the square and two p = −3.00 μC charges at the other corners. a.)Find the electric field at the center of the square. Enter a positive value if the electric field is straight down and enter a negative value if the electric field is straight up. b.)Find the potential at the center of the square.

At each of the four corners of a square with side length a, there is a...

At each of the four corners of a square with side length a, there is a charge +q. How many other charges are exerting electric forces on the charge at the lower-right corner? The square is placed so that its sides are either parallel or perpendicular to the x-axis.

A cube of side L has one corner at the origin of coordinates, and extends along...

A cube of side L has one corner at the origin of coordinates, and extends along the positive x, y, and z axes. Suppose the electric field in this region is given by E = (a + b y2) j, where j denotes the unit vector in the y direction, y denotes distance in the y direction in meters, and a and b are constants. Find the charge Q enclosed within the cube.

Question: Consider a rhombus with equal sides and point charges Q, Q, -Q, -Q in the...

Question: Consider a rhombus with equal sides and point charges Q, Q, -Q, -Q in the four corner sketch the electric field lines (this structure is called quadrupole) Question: How many electrons should we transfer from Earth to Sun in order to match the gravity force between the two? Suppose we take those electrons from a cube shape piece of Al, one electron per atom. What would be the size of the cube?