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#6) (25 pts total) An infinitely long cylinder of radius R carries a “frozen-in” magnetization parallel...
5. An infinitely long cylinder of radius R carries a frozen-in" magietization parallel to z-axis and is given by M = ksi, where k is a constant and s is the distance from the axis. There is no free current anywhere. Find the magnetic field inside and outside the cylinder.
(2) 4.[4pts) An infinitely long cylinder of radius R carries NO free current but magnetization M=ks, where k > 0 is a constant and s is the cylindrical radius from the axis. Find the magnetic field B due to M both inside and outside of the cylinder.
3) Didn't I just ask this? A long circular cylinder of radius R carries a magnetization M ksp, where k is a constant, s is the distance from the axis, and ф is the azimuthal unit vector. a) Use ф H- dl = hemet to determine the auxiliary field (H field) both inside and outside of the cylinder b) use H = (110)2-M to determine the magnetic field (B-field) both inside and outside of the cylinder
Problem 4, 30 marks The infinitely long conducting cylinder of radius R carries the volume current density directed along its axis whose absolute value is a cubic function of the distance from the center of the cylinder r, j(r)-br3, where b is a known constant. a. Find the magnitude and direction of the magnetic field B forr>R. b. Find the magnitude and direction of the magnetic field B for r<R. c. Imagine that the conductor has magnetic permeability H (5...
An infinitely long circular cylinder carries a permanent magnetization M = ks^2 zˆ. a) Calculate the bound current densities Jb and Kb. b) Calculate the total current due to Jb circulating around the axis of the cylinder within a section of length ∆z = L, and indicate its direction. (Show your integral explicitly.) c) Calculate the total current due to Kb circulating around the axis of the cylinder within a section of length ∆z = L, and indicate its direction....
An infinitely long, straight, cylindrical wire of radius R carries a uniform current density J. Using symmetry and Ampere's law, find the magnitude and direction of the magnetic field at a point inside the wire. For the purposes of this problem, use a cylindrical coordinate system with the current in the +z-direction, as shown coming out of the screen in the top illustration. The radial r-coordinate of each point is the distance to the central axis of the wire, and...
Electrostatics problem 2. An infinitely long circular cylinder of radius a and dielectric constant E is placed with its axis along the z-axis and is put in an electric field which would have been uniform in the absence of the cylinder, pointing along the x-axis (see figure). Find the total electric field at all points outside and inside the cylinder. Find the bound surface charge density.
An infinitely long cylinder of radius R = 3 cm carries a uniform charge density p = 17 Cm. Calculate the electric field at distance r = 18 cm from the axis of the cylinder. Select one: O a. 8.8x10° NC b. 2.8x10NC c. 6.8x103 N/C d. 0.8x10° NIC O O e. 4.8x10 N/C
Suppose that you have a very long cylinder (treat it as infinitely long) with a uniform charge density p (coulombs per cubic metre). The cylinder has a radius a. Let the axis of the cylinder be the 2- axis. The cylinder is rotating about this axis with a constant angular speed w in a counterclockwise direction. @=w2 a. [5 points] What is the current density ✓ at a general point in the cylinder, at a distance r from the ĉ-axis,...
1. Suppose that you place an uncharged, infinitely long metal cylinder of radius a in ain initially uniform electric field EEo, such that the cylinder's axis lies along the z axis. The resulting electrostatic potential is V(x,y, z)V for points inside the cylinder, and Еда 2x V(x, y, z)-Й-Box + x2+3,2 for points outside the cylinder, where Vo is the (constant) electrostatic potential on the conductor. (a) Find the electric field, E, from the given voltage. (b) Find the charge...