A sphere of radius R, centered at the origin, carries charge density p = 3kcosO/rR4 where...

A solid sphere, radius R, is centered at the origin. The “northern” hemisphere carries a uniform...

A solid sphere, radius R, is centered at the origin. The “northern” hemisphere carries a uniform charge density ρ0, and the “southern” hemisphere a uniform charge density −ρ0. Find the approximate field E(r,θ) for points far from the sphere (r ≫ R).

A grounded conducting sphere of radius R is centered at the origin and is in a...

A grounded conducting sphere of radius R is centered at the origin and is in a uniform electric field E = E0 z. Find an expression for the potential outside the sphere, i.e. for r > R. Find an expression for the induced charge density on the surface of the sphere . If the sphere is now disconnected from ground and there is an additional charge Q placed on the sphere, what is the new expression for the potential?

A metallic sphere centered at the origin has density of 24.6nC/m^2. In r=2 the potential is...

A metallic sphere centered at the origin has density of 24.6nC/m^2. In r=2 the potential is 500V and the magnitude of the electrical field is 250 V/m. Determine the radius of the sphere.

A sphere with radius R carries a positive charge density of ρ=2r3, take the potential at...

A sphere with radius R carries a positive charge density of ρ=2r3, take the potential at infinity is 0, find the electric potential everywhere (r<R and r>R).

An insulating sphere of radius a has charge density p(r) = P0r^2, where P0 is a...

An insulating sphere of radius a has charge density p(r) = P0r^2, where P0 is a constant with appropriate units. The total charge on the sphere is -3q. Concentric with the insulating sphere is a conducting spherical shell with inner radius b > a and utter radius. The total charge on the shell is +2q. Determine a. the magnitude of the electric field at the following locations: (i) r < a, (ii) a < r < b, (iii) b <...

An uncharged conducting sphere of radius 2b is centered on the origin and has a spherical...

An uncharged conducting sphere of radius 2b is centered on the origin and has a spherical cavity of radius b that is also centered on the origin. 1. If a charge of +q is at the origin, explain why the surfaces at r=2b and r=b each have a net charge of +q and −q, respectively, and not, say, +q/2 and −q/2. 2. Repeat this question for the case where the inner surface of the cavity is not spherical (but the...

A circular ring of charge, with radius R,is placed in the xy-plane and centered on the...

A circular ring of charge, with radius R,is placed in the xy-plane and centered on the origin. The linear charge density of the ring isλ=λ_o*cos^2(φ), where φ is the cylindrical polar coordinate such that any point in space is indicated by (r, φ, z). Find the electric potential anywhere on the z-axis as a function of z . Using this electric potential find the electric field anywhere on the z-axis also as a function of z

The potential at the surface of a sphere (radius R) is given by Vo=Kcos3D, Where D...

The potential at the surface of a sphere (radius R) is given by Vo=Kcos3D, Where D is theta,K is a constant. Find the potential inside and outside the sphere, as well as the surface charge density s(D) on the sphere.(Assume there is no charge inside or outside the sphere).

A sphere of radius R carries a polarization , where is a constant. (note that there...

A sphere of radius R carries a polarization , where is a constant. (note that there is no free charge) What is the surface bound charge and the volume bound charge . Find the electric field inside and outside the sphere. (Hint: you can use the result of Q1 to calculate the electric field inside the sphere, that the total charge due to polarization vanishes. Outside the sphere, calculate the enclosed charge from the volume bound charge)

For a charged hollow metal sphere with total charge Q and radius R centered on the...

For a charged hollow metal sphere with total charge Q and radius R centered on the origin: True False  the charge is on the inside surface. True False  the field for r > R will be the same as the field of a point charge, Q, at the origin. True False  the field on the outside is perpendicular to the surface. True False  inside the metal the field is strongest. True False  the field inside the shell is zero. True False  only positive charges can be...