calculate the magnetic field inside a uniformly magnetized sphere

A spherical shell with inner radius r1 and outer radius r2 is uniformly magnetized. Use Poisson’s...

A spherical shell with inner radius r1 and outer radius r2 is uniformly magnetized. Use Poisson’s relation to find the magnetic field B inside the inner surface of the shell, outside the outer surface of the shell and within the magnetized material of the shell. Use SI units.

A spherical shell with inner radius r1 and outer radius r2 is uniformly magnetized. Use Poisson’s...

A spherical shell with inner radius r1 and outer radius r2 is uniformly magnetized. Use Poisson’s relation to find the magnetic field B inside the inner surface of the shell, outside the outer surface of the shell and within the magnetized material of the shell. Use SI units.

A conducting sphere of radius a is uniformly magnetized with a magnetization of magnitude M. It...

A conducting sphere of radius a is uniformly magnetized with a magnetization of magnitude M. It also has a net charge Q. Find the poynting vector.

Derive the expression for the electric field inside of a uniformly charged solid (non- conducting) sphere...

Derive the expression for the electric field inside of a uniformly charged solid (non- conducting) sphere of radius R using Gauss’ law. (b) Graph the electric field magnitude as a function of distance from the sphere center (include distances both less than and greater than the sphere’s radius); be sure to adequately label the graph.

A spherical shell, with inside radius R1 and outside radius R2, is uniformly magnetized in the...

A spherical shell, with inside radius R1 and outside radius R2, is uniformly magnetized in the direction of the z- axis. The magnetization in the shell is Mo = Mok. Find the scalar potential ɸ* for points on the z-axis, both inside and outside the shell

4. a. Show that the electric field vanishes everywhere inside a uniformly charged hollow sphere. This...

4. a. Show that the electric field vanishes everywhere inside a uniformly charged hollow sphere. This is done as part of example 22.5 in the book. b. Use this result and a symmetry argument to show that the the field in the equatorial plane of a (hollow) hemisphere is perpendicular to the plane (not just on the axis of rotational symmetry).

Consider a uniformly magnetized infinite circular cylinder, of radius S0, with its axis coinciding with the...

Consider a uniformly magnetized infinite circular cylinder, of radius S0, with its axis coinciding with the z-axis. The magnetization inside the cylinder is M = M0z ?. i) Find H, B, JB, and KB everywhere. ii) What type of magnetic material is this and why?

the electric field produced by a uniform sphere of charge (both inside and outside the sphere)....

the electric field produced by a uniform sphere of charge (both inside and outside the sphere). We inherently assumed the sphere was made of a dielectric material. How would the electric field be different if the sphere were a conductor with the same total net charge (q)? Your answer does not need to involve an equation. Instead, provide a concise explanation for why the electric field would be different or the same (both inside and outside the sphere).

Consider a solid uniformly charged copper sphere with charge Q and radius R. Showing all Steps,...

Consider a solid uniformly charged copper sphere with charge Q and radius R. Showing all Steps, (a) Calculate the potential of the spherical charge inside and outside of the sphere. (b) Calculate the electric field of the spherical charge from the potential in part (a) for the inside and outside regions.

Are there more magnetic field lines inside or outside a magnet?

Are there more magnetic field lines inside or outside a magnet?