The field just outside a 2.63cm -radius metal ball is 2.98

A solid metal ball of 1 m radius is centered in and surrounded by a thick...

A solid metal ball of 1 m radius is centered in and surrounded by a thick walled spherical hollow metal ball whose inner wall radius is 8m and outer wall radius is 9m. Both balls are isolated and then additional charge is deposited on both. If the E field points outward at 3.5m from the center of the inner ball and has a value of 77.1 N/C. what is the surface charge density on the surface of the inner ball?...

A thin ball shell is shaped like a hollow ball with a radius of 42.8 cm....

A thin ball shell is shaped like a hollow ball with a radius of 42.8 cm. The material is a conductor with charge 0.8 nC A point charge of -5.4 nC is placed in the center of the ball. How many N / C is the electric field just outside the ball? Remember positive is outwards I did this: got Total charge Qencloced = -4.6*10^-9 C Found the field E=(Qencloced/Epsilon) divided by 4*pi*speed squared Got 225.80 N/C. The answer in...

As part of an experiment in physics lab, small metal ball of radius r = 2.1...

As part of an experiment in physics lab, small metal ball of radius r = 2.1 cm rolls without slipping down a ramp and around a loop-the-loop of radius R = 3.7 m. The ball is solid with a uniform density and a mass M = 336 g. 1) How high above the top of the loop must it be released in order that the ball just makes it around the loop? m 2) Now instead of a sphere, what...

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...

A 4.6-kg metal ball of radius 30 cm is attached by a string of length 50...

A 4.6-kg metal ball of radius 30 cm is attached by a string of length 50 cm at its center to a vertical wall. The coefficient of friction between the wall and the ball is 0.20. Determine the tension on the string.

Find the electric field inside and outside a charged conducting ring of radius a *using legendre...

Find the electric field inside and outside a charged conducting ring of radius a *using legendre polynomials

10. A shell of solid metal sphere of outer radius Ro = 2m and inner radius...

10. A shell of solid metal sphere of outer radius Ro = 2m and inner radius of R1 = 1m has a charge of Q1 = 4C placed on it. After the charge is placed on the sphere, a charge of Q2 = 6C is then placed at the center of the sphere. Find the electric field everywhere in the sphere. What are the charges on the inside of the sphere, and outside the sphere.

a) By using Gauss’s law, find the electric field inside, outside and inbetween two concentric spherical...

a) By using Gauss’s law, find the electric field inside, outside and inbetween two concentric spherical metal shells, assuming that the inner shell, of radius a, carries a charge of -Q and the outer shell, of radius b, carries a charge of Q. b) By making use of the result in part (a), find the energy stored in the system made of two concentric spherical metal shells. c) By using the result in part (a) find the electric potential difference...

Question 1 The electric field 10.0 cm from the surface of a copper ball of radius...

Question 1 The electric field 10.0 cm from the surface of a copper ball of radius 5.0 cm is directed toward the ball’s center and has magnitude 400 N/C. How much charge is on the surface of the ball? A. Impossible to determine B. None of the above C. 0.1 nC D. 0.4 nC

The simplest model of an atomic nucleus is a solid ball of radius "a" having uniform...

The simplest model of an atomic nucleus is a solid ball of radius "a" having uniform charge density "rho". A) Find the electrical field E at all points using Gauss' Law. (inside sphere, outside sphere) B) By integrating appropriately, find the continuous potential function "phi" such that "phi"=0 at the origin.