a) A line of charge is along the z-axis, from –L to L. If the distribution...

A cylinder (bottom face at z= - L, top face at z = L, radius R,...

A cylinder (bottom face at z= - L, top face at z = L, radius R, centered along the z-axis) carries a volume charge distribution ?(?,?, ?) = ?o ( ?/ ? ) ???^2?. a. Calculate the monopole and dipole moments of this charge distribution b. Find the leading order terms for the potential an the electric field at the point (x = 25R, y = 25R, z = 25L)

An infinite line of positive charge lies along the y axis, with charge density λ =...

An infinite line of positive charge lies along the y axis, with charge density λ = 2.30 μC/m. A dipole is placed with its center along the x axis at x = 28.0 cm. The dipole consists of two charges ±10.0 μC separated by 2.00 cm. The axis of the dipole makes an angle of 45.0° with the x axis, and the positive charge is farther from the line of charge than the negative charge. Find the net force exerted...

A rod of length 2l lies on the x-axis from x = −l to x =...

A rod of length 2l lies on the x-axis from x = −l to x = +l. The left half of the rod carries uniform negative charge density −λ while the right half carries a uniform positive charge density +λ. (a) What is the net charge of each half of the rod? What is the total charge of the entire rod? (b) Determine an exact expression for the magnitude of the electric field at an arbitrary point along the x-axis...

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?

Assume there is a line of linear charge density λ(z) = αz and length 2a that...

Assume there is a line of linear charge density λ(z) = αz and length 2a that lies along the z-axis. The line is centered at the origin, so that one end is at z = −a with the other at z = a. What is the potential difference V(0, 0, 2a) − V(0, 0, −2a)?

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 >...

A short, solid cylinder (centered on the z-axis, top face at z = L, bottom face...

A short, solid cylinder (centered on the z-axis, top face at z = L, bottom face at z =0, radius R) carries a volume charge distribution ρ(φ) = ρ0cosφ. a. Find an expression for the potential at an arbitrary point (s,φ, z). b. Use your result from part (a) to find the potential the potential at the origin, and the point (x = R, y = 0, z = 0). c. Graph the potential as a function of position along...

You have a line charge that lies along the x axis from x = - 13.0...

You have a line charge that lies along the x axis from x = - 13.0 cm to x = +11.2 cm, and you want to find the electric potential on the y-axis at x = 0, y = 6.43 cm. The line charge density as a function of x is given by ?(x)    =   277 ?C/m      x0.242 m where x must be in m. Part (a) Draw a diagram of your version of the problem, and use it...

An infinitely long cylinder (radius R, centered along the z-axis) carries a surface charge distribution σ(s...

An infinitely long cylinder (radius R, centered along the z-axis) carries a surface charge distribution σ(s = R,φ) = σ0 (4sinφ + 6cos2φ) . Using electricity and magnetism a. Find expressions for the potential and electric field at arbitrary points inside and outside the cylinder. b. Find the force on a test charge 3q at the point (x = 3R, y = R, z = 4R), assuming the test charge is too small to affect the potentials / fields found...

let us suppose that a uniform, thin line of charge Q stretches from z=0 to z=L...

let us suppose that a uniform, thin line of charge Q stretches from z=0 to z=L on the ˆz-axis. calculate the electric field produced by the line at a point r=xˆx for x>0. This point is not equidistant from the two ends—does the electric field have both an x and a z component there?