Two uniformly charged, infinite, nonconducting planes are parallel to a yz plane and positioned at x...

Two uniformly charged, infinite, nonconducting planes are parallel to a yz plane and positioned at x...

Two uniformly charged, infinite, nonconducting planes are parallel to a yz plane and positioned at x = -42 cm and x = +42 cm. The charge densities on the planes are -41 nC/m2 and +21 nC/m2, respectively. What is the magnitude of the potential difference between the origin and the point on the x axis at x = +84 cm? (Hint: Use Gauss' law for planar symmetry to determine the electric field in each region of space.)

Two uniformly charged, infinite, nonconducting planes are parallel to a yz plane and positioned at x...

Two uniformly charged, infinite, nonconducting planes are parallel to a yz plane and positioned at x = -44 cm and x = +44 cm. The charge densities on the planes are -55 nC/m2 and +17 nC/m2, respectively. What is the magnitude of the potential difference between the origin and the point on the x axis at x = +89 cm? (Hint: Use Gauss' law for planar symmetry to determine the electric field in each region of space.)

An infinite, uniformly charged plane is placed in the yz plane, at x = 0. a....

An infinite, uniformly charged plane is placed in the yz plane, at x = 0. a. What are the symmetries of this plane? b. Use one of these symmetries to determine the direction of the electric field along the x -axis, for x > 0. c. How is the electric field for x < 0 related to the electric field for x > 0 along the x -axis? d. Use some other symmetries to explain why the electric field cannot...

Three parallel, “infinite” sheets of charges are horizontal, parallel to the x-y plane. The sheet at...

Three parallel, “infinite” sheets of charges are horizontal, parallel to the x-y plane. The sheet at z = -5 m is charged at -2 μC/m2. The sheet at z = 0 is charged at 9 μC/m2. The sheet at z = 5 cm is charged by -15 μC/m2. Find the magnitude and direction of the electric field at a point P with Cartesian coordinates (2 m, -3 m, 6 m).

An infinite plane of surface charge density σ = 4.5 nC/m2 lies in the x =...

An infinite plane of surface charge density σ = 4.5 nC/m2 lies in the x = 0.00 m plane, and a second infinite plane of surface charge density σ = 4.50 nC/m2 lies in the x = 0.0200 m plane. Find: a. the electric field at (i) x = 0.0180 m and (ii) x = 0.0500 m b. the electric potential difference between the 2 planes.

a. Consider two infinite sheets parallel to the xy plane, separated by distance d, carrying charge...

a. Consider two infinite sheets parallel to the xy plane, separated by distance d, carrying charge densities +? and -?. Solve for and sketch the potential as a function of z. b. Consider two disks of radius R parallel to the xy plane, centered on the z axis and separated by distance d, carrying charge densities +? and -?. (In a real capacitor, the charge density will not be strictly uniform, but we will continue to ignore that for the...

The distance between an infinite planar sheet, uniformly charged with +10nC/, and a -5.0 nC point...

The distance between an infinite planar sheet, uniformly charged with +10nC/, and a -5.0 nC point charge is 4.0 cm. Calculate the electric force on the point charge and indicate its direction. Determine the location(s), if any, where the electric field vanishes. c. If the point charge is free to move, calculate its speed when it strikes the sheet. Please use conversation of energy. The mass of the point charge is 2.0 mg. Neglect gravity

An infinite sheet of charge that has a surface charge density of 19 nC/m2 lies in...

An infinite sheet of charge that has a surface charge density of 19 nC/m2 lies in the yz plane, passes through the origin, and is at a potential of 0.7 kV . A long wire having a linear charge density of 91 nC/m lies parallel to the y axis and intersects the x axis at (4.2 m, 0, 0). What is the potential energy of a 1.9 nC charge placed at (1.1 m, 0, 0) ? The value of the...

An infinitely large positively charged nonconducting sheet 1 has uniform surface charge density σ1 = +130...

An infinitely large positively charged nonconducting sheet 1 has uniform surface charge density σ1 = +130 nC/m2 and is located in the xz plane of a Cartesian coordinate system. An infinitely large positively charged nonconducting sheet 2 has uniform surface charge density σ2 = +90.0 nC/m2 and intersects the xz plane at the z axis, making an angle θ = 30∘ with sheet 1. Part A Determine the expression for the electric field in the region between the sheets for...

Consider an infinite plane of charge with a charge density of +10 µC/m2. Assume that this...

Consider an infinite plane of charge with a charge density of +10 µC/m2. Assume that this plane is on the y-and z-axes. That is, assume it is perpendicular to the x-axis and that it passes through the origin. a) What would be the electric field strength and direction at the point (5 m, 0, 0)? The strength is___________N/C The direction is Answer: -x, x, -y, y, -z, or z b) What would be the electric field strength and direction at...