Consider two media in contact with each other. The surface has surface charge density ρs and...

Consider a charged spherical shell of radius a having a constant surface charge density σ0, rotating...

Consider a charged spherical shell of radius a having a constant surface charge density σ0, rotating about the z-axis with angular frequency ω. (a) Find the electric and magnetic fields outside of the shell. (b) What is the electric pressure on the surface charges? What is the magnetic pressure due to the surface currents? (c) Find the Poynting vector outside of the shell. (d) What is the angular momentum density outside of the shell? What is the total angular momentum...

Consider an infinite plane dielectric slab of thickness d sandwiched between two infinite plane sheets of...

Consider an infinite plane dielectric slab of thickness d sandwiched between two infinite plane sheets of equal and opposite uniform charge densities ρs and –ρs in the z = 0 and z = d planes, respectively. Answer the following: (a) In the absence of the dielectric, find the electric field between the sheets of charge. (b) Assuming a uniform polarization P in the dielectric, show that there is no polarization volume charge, and that the polarization surface charge is given...

Consider the following volume, surface, and line charge distributions. Find the total charge in each case:...

Consider the following volume, surface, and line charge distributions. Find the total charge in each case: (a) A spherical shell: ρv = ρvo (a < r < b) (b) A charged disk: ρs = ρso (0 < ρ < a, z = 0) (c) A charged loop at the equator: ρℓ = ρℓo cos2f (ρ = a, z = 0)

Consider a rotating disk of radius R with uniform surface charge density σ and angular rotation...

Consider a rotating disk of radius R with uniform surface charge density σ and angular rotation speed ω. (a) show that for an annular strip of radius r, and width dr that the current dI = ωσrdr HINT: see class notes from previous week (b) Show that the magnetic field in the center of the disk is given by B = 1μ0σωR 2

We have a square surface of side L that has a surface charge density of 2C...

We have a square surface of side L that has a surface charge density of 2C / L ^ 2. - A Gaussian sphere-shaped surface whose center coincides with the center of the loaded frame is constructed. The radius of the sphere is L / 2. What will be the electric field flow through said Gaussian surface? - Now a Gaussian sphere-shaped surface is built that completely encloses the loaded frame. What will be the electric field flow through that...

Two vertical infinite charged sheets are parallel to each other and separated by 0.500 meters. The...

Two vertical infinite charged sheets are parallel to each other and separated by 0.500 meters. The sheet on the left has a surface charge density of sigma= +10.0 microC/m^2, while the sheet on the right has a surface charge density of sigma = -5.00 microC/m^2. a) What is the magnitude and direction of the electric field between the plates? b.) What is the magnitude and direction of the electric field in the region that is to the left of both...

Consider two electric dipoles in empty space. Each dipole has zero net charge. Does an electric...

Consider two electric dipoles in empty space. Each dipole has zero net charge. Does an electric force exist between the dipoles; that is, can two objects with zero net charge exert electric forces on each other? If so, is the force one of attraction or of repulsion?

Consider two long straight wires parallel to each other. The wire A on the left has...

Consider two long straight wires parallel to each other. The wire A on the left has a current of I1= 3 A and is separated by 5 m from the wire B on the right that carries I2= 2 A of current. The currents are flowing in the same direction as in the figure. a) Consider a point P that is 2 m to the right of wire B. Determine the magnitude including unit and direction of the magnetic field...

1. A 30 cm radius hollow spherical conductive shell of has a surface charge density of...

1. A 30 cm radius hollow spherical conductive shell of has a surface charge density of 10 µC/m2, a point charge Q1 is in its center. Find the electric flux through the spherical surface centered at Q1: a. if the value is Q1= +3.5x10-6 C charge b. if the value is Q1= -2.5x10-6 C charge c. What would be the electric field in each case? Please explain how you got the answer, having trouble understanding this and can't seem to...

Consider two parallel, oppositely-charged plates, separated by 26.0 cm. The surface charge density on the first...

Consider two parallel, oppositely-charged plates, separated by 26.0 cm. The surface charge density on the first plate is σ = -7.28×10-3 C/m2. What potential difference does a charge move through when it travels from the first plate to the second?