Find the electric flux density D at P (4, 1.5π, z = 1) due to the...

Illustrate and Solve the following: i. The electric field intensity E at P(4, 1.5π, z =...

Illustrate and Solve the following: i. The electric field intensity E at P(4, 1.5π, z = 1) due to a a square surface charge distribution with ρS = 2ε0 C/m2 on the y = 0 plane with x and z both ranging from -1 to +1 m. is _________. j. The electric field intensity E at P(4, 1.5π, z = 1) due to a a square surface charge distribution with ρS = 2ε0 C/m2 on the y = 1 plane...

Determine the electric field intensity ans the electric flux density at the origin that results from...

Determine the electric field intensity ans the electric flux density at the origin that results from your five selected charged elements if the medium has a relative permittivity of 2.3 1)125 nC point charge located at (15,-1,-2) 2)Finite line with length charge density -12 nC/m extending from (-6,5,2) to (6,5,-2) 3)Infinite line with length charge density 5 nC/m at intersection of x = 4 and y = -1 4)Infinite plane at x = 10 with surface charge density -23 nC/m2...

A line charge sits on the z-axis from z=0 to z=a. The charge density, lambda, varies...

A line charge sits on the z-axis from z=0 to z=a. The charge density, lambda, varies linearly with the expression: lambda=(lambda0/a)z. a, What is the electric potential, V, due to this line charge, everywhere on the x-axis? b, How much mechanical work is needed to move a charge Q from z=+infinite to the position on the x-axis at x=d?

Given On the y = 0 plane, at x = -2 m. line, ρL1 = -2πε0...

Given On the y = 0 plane, at x = -2 m. line, ρL1 = -2πε0 C/m and at x = -1 m. line. ρL2 = -πε0 C/m: Find a. Electric flux density D at P (4, 1.5π, z = 0) b. Electric flux density D at P (1, π/2, π/2)

GOAL Use the superposition principle to calculate the electric field due to two point charges. Consider...

GOAL Use the superposition principle to calculate the electric field due to two point charges. Consider the following figure. The resultant electric field  at P equals the vector sum 1 + 2, where 1 is the field due to the positive charge q1and 2 is the field due to the negative charge q2.Two point charges lie along the x-axis in the x y-coordinate plane. Positive charge q1 is at the origin, and negative charge q2 is at (0.300 m, 0). Point...

An infinite line of charge with charge density λ1 = 1.4 μC/cm is aligned with the...

An infinite line of charge with charge density λ1 = 1.4 μC/cm is aligned with the y-axis as shown. 1)What is Ex(P), the value of the x-component of the electric field produced by by the line of charge at point P which is located at (x,y) = (a,0), where a = 8.2 cm? 2)What is Ey(P), the value of the y-component of the electric field produced by by the line of charge at point P which is located at (x,y)...

It was shown in Example 21.11 (Section 21.5) in the textbook that the electric field due...

It was shown in Example 21.11 (Section 21.5) in the textbook that the electric field due to an infinite line of charge is perpendicular to the line and has magnitude E=λ/2πϵ0r. Consider an imaginary cylinder with a radius of r = 0.230 m and a length of l = 0.480 m that has an infinite line of positive charge running along its axis. The charge per unit length on the line is λ = 4.60 μC/m. What is the electric...

Given: Q = 4πε0 C at the origin and on the z = 0 plane: at...

Given: Q = 4πε0 C at the origin and on the z = 0 plane: at x = -2 m. line, ρL1 = -2πε0 C/m; at x = -1 m.line, ρL2 = -πε0 C/m; at x = 1 m.line, ρL3 = πε0 C/m; and at x = 2 m.line, ρL4 = 2πε0 C/m. (i) Find the total flux crossing the surfaces of the box whose center is at the origin and with 0 <= |x|, |y|, |z| <= 3. (ii)...

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...

A thin rod extends along the z-axis form z = -d to z = d. The...

A thin rod extends along the z-axis form z = -d to z = d. The rod carries a charge Q uniformly distributed along its length 2d with linear charge density λ = Q/2d. a) Find the electric potential at a point z > d along the z-axis. Indicate clearly where you have chosen your zero reference point for your potential. b) Use the relationship E = - ∇ V to find the electric field at a point z >...