5. PROBLEM: GUASS'S LAW I Use Guass's law to obtain the electric field for each of...

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 positive charge +Q is distributed uniformly throughout the volume of an insulating sphere with radius...

A positive charge +Q is distributed uniformly throughout the volume of an insulating sphere with radius R. Find the electric potential V at a point P a distance r from the center of the sphere. Plot the electric potential V vs. the distance r from the center of the sphere for 0 < r < 2R

Use Ampere’s Law to determine the magnetic field as a function of r (distance from the...

Use Ampere’s Law to determine the magnetic field as a function of r (distance from the symmetry axis) both inside and outside an infinitely long cylinder of radius R, carrying a current Iothat is(show all relevant steps and any symmetry arguments in part a, then you don’t have to repeat them in part b): a) uniformly distributed over the surface of the cylinder (i.e., at r = R) b) uniformly distributed throughout the cylinder

Consider a sphere of radius R that has been given a charge Q. A.) Use Gauss'...

Consider a sphere of radius R that has been given a charge Q. A.) Use Gauss' Law to derive the electric field outside the sphere.Does your answer depend on whether the sphere is made of conducting material or whether it is made of insulating material with the charge spread uniformly throughout this volume? B.) Sketch the shape of the graph E(r) for bother conducting and insulating cases.

A net electric charge of 2.87 ?C is placed on a conducting sphere. The radius of...

A net electric charge of 2.87 ?C is placed on a conducting sphere. The radius of the sphere is R = 20.5 cm. What is the magnitude of the electric field at a distance of d1 = 26.8 cm away from the center of the sphere? Tries 0/12 What is the magnitude of the electric field at a distance of d2 = 14.2 cm away from the center of the sphere? Tries 0/12 The same amount of electric charge is...

1.A particle of charge ​q​ and mass ​m​ experiences a uniform electric field ​E​. If the...

1.A particle of charge ​q​ and mass ​m​ experiences a uniform electric field ​E​. If the particle starts at rest, find (a) its speed after it has travelled a distance ​d​ and (b) the magnitude of the electric potential difference through which it passed 2. Find the electric field of a uniformly charged solid sphere both inside and outside the sphere if the total charge is ​Q​0​ and the radius of the sphere is ​d​.

Three charges are enclosed in a cylindrical shell. What is the flux coming through the closed...

Three charges are enclosed in a cylindrical shell. What is the flux coming through the closed surface of the shell? Let q1 = 6 nC, q2 = 5 nC, q3 = -10 nC. What is the electric field of a point charge of 57 nC at a point 10 cm away via Gauss' Law? Challenging: You have a solid sphere of charge Q and radius R. The charge is uniformly distributed throughout the sphere. Which of the following is correct?...

a) Use the Gauss Law to find the electric field at point P at distance r>R...

a) Use the Gauss Law to find the electric field at point P at distance r>R from the center of the very long cylinder with volumetric charge density ? and radius R b) Use the Gauss Law to find the electric field at point P at distance r<R from the center of the very long cylinder with volumetric charge density ? and radius R Make sure to briefly explain all the steps (annotate them briefly, as in class notes). Take...

Which one of the following statements is true? 1. In equilibrium all of any excess charge...

Which one of the following statements is true? 1. In equilibrium all of any excess charge stored on a conductor is on the outer surface. 2. In equilibrium the electric field inside a conductor is zero. 3. In a spherical insulator with radius R on which charge q is uniformly distributed, the electric field at a distance of R/4 from the center of the sphere is ¼ of the field at the surface of the sphere

A hollow, spherical, ideal insulator (R=0.075m) has a net charge of +3.75μC, with the charge is...

A hollow, spherical, ideal insulator (R=0.075m) has a net charge of +3.75μC, with the charge is distributed uniformly throughout its volume A- Calculate the total electric flux though a “Gaussian” sphere (with radius r=0.065m) centered on the center of the charged sphere. B- Find the magnitude and direction of the electric field at a point, r=0.115m, directly below the center of the sphere.