The electrostatic potential on the surface of a sphere of radius a is given by V(theta)=V0cos2(theta)....

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 surface charge density sigma(theta)=[sigma_o(cos(theta))] is glued to the surface of a spherical shell of radius...

A surface charge density sigma(theta)=[sigma_o(cos(theta))] is glued to the surface of a spherical shell of radius R. There is a vacuum with no charges both inside and outside of the shell. Calculate the electrostatic potential and electric field both inside and outside of the spherical shell. Side note: sigma_o is sigma subscript o.

A surface charge density sigma(theta)=[sigma_o(cos(theta))] is glued to the surface of a spherical shell of radius...

A surface charge density sigma(theta)=[sigma_o(cos(theta))] is glued to the surface of a spherical shell of radius R. There is a vacuum with no charges both inside and outside of the shell. Calculate the electrostatic potential and the electric field both inside and outside the spherical shell. (the "_" is a subscript in sigma_o).

A conducting sphere of radius "a" is placed in a uniform electrostatic field E. If the...

A conducting sphere of radius "a" is placed in a uniform electrostatic field E. If the sphere is well insulated, find the expressions for potential and electric fields V and E at point P lying outside the sphere. Also obtain the expression for the induced surface charge density and show that it forms a dipole distribution. Specify boundary conditions.

a sphere shell of radius R is at a potential V(thetha) = 1+cos(thetha). use laplaces equation...

a sphere shell of radius R is at a potential V(thetha) = 1+cos(thetha). use laplaces equation to find the potential inside and outside of the sphere.

Consider a two-dimensional potential problem for a region bounded by four planes x=0, y=0, and y=1....

Consider a two-dimensional potential problem for a region bounded by four planes x=0, y=0, and y=1. There are no charges inside the bounded region. The boundaries at x=0, x=1, and y=0 are held at zero potential. The potential at the boundary y=1 is given by V(x,1)=V0sin(pi*x) a.) find the electrostatic potential V(x,y) everywhere inside this region by solving the Laplace equation in two dimensions using the method of separation of variables. b.) Calculate the surface charge density on the boundary...

Make a side by side comparison for the solutions of example 3.9 (the potential inside and...

Make a side by side comparison for the solutions of example 3.9 (the potential inside and outside a sphere with charge density ? = ? cos ? glued on its surface) and example 4.2 (the potential inside and outside a uniformly polarized sphere). Compare them according to: a) The given information b) The equation to be solved (Poisson’s or Laplace’s)c) The boundary conditions d) Applying the boundary conditions e) Final solution Example 3.9. A specified charge density u0(0) is glued...

A thin, uniformly charged spherical shell has a potential of 727 V on its surface. Outside...

A thin, uniformly charged spherical shell has a potential of 727 V on its surface. Outside the sphere, at a radial distance of 20.0 cm from this surface, the potential is 403 V. (1) Calculate the radius of the sphere. (2) Determine the total charge on the sphere (3) What is the electric potential inside the sphere at a radius of 3.0 cm (4) Calculate the magnitude of the electric field at the surface of the sphere. (5) If an...

Q2a) Show that the potential at the surface of a uniformly charged sphere of radius R...

Q2a) Show that the potential at the surface of a uniformly charged sphere of radius R is V=Kq/R where K = 1/4πɛ₀ and the zero of potential is at infinity). Hence derive an expression for the potential energy of the sphere. (Hint, assemble the sphere from the charges at infinity) b) A parallel plate capacitor has conducting plates, each of area A, situated at y=0 and y=d. two parallel dielectric sheets occupy the space between the plates. Dielectric of relative...

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).