2. (10 points) in class we found the Gauss's law for electricity gave us a value...
2. (10 points) In class we found the Gauss's law for electricity gave us a value for the electric field a distance r away (E = (1/41ɛo) (Aenclosed/r?). You have a conductive solid sphere (radius of a) inside a conductive shell (inner radius of b and outer radius of c). The sphere has a charge of +4Q while the shell has a charge of +10Q. Find the following: a. What is the electric field for r<a? What is the electric...
Gauss’s law for electricity gave us a value for the electric field a distance r away (E = (1/4πε0)(qenclosed/r2). You have a conductive solid sphere (radius of a) inside a conductive shell (inner radius of b and outer radius of c). The sphere has a charge of +4Q while the shell has a charge of +10Q. Find the following: a. What is the electric field for r<a? What is the electric field for b>r>a? b. What is the net charge...
Q3: Gauss's Law Problem Statement A-100 nC point charge sits at the center of a hallow spherical shell. The shell with radius 0.1 cm and negligible thickness, has a net charge of 200 nC. Find the electric field strength a) inside the sphere at r=0.05cm from the center, and b) outside the sphere at r=0.15cm from the center. In what direction does the electric field point in each case? Visual Representation • Draw a sketch of the charge distribution. •...
A small conducting spherical shell with inner radius a and outer radius b is concentric with a larger conducting spherical shell with inner radius c and outer radius d. The inner shell has a total charge of -2q and the outer shell has a total charge of +4q. The total charge on the outer surface of the large shell is +2q. The radial component of the electric field in the region c <r < d is given by -2q/(4nε0r2). The total charge on...
A small conducting spherical shell with inner radius a and outer radius b is concentric with a larger conducting spherical shell with inner radius c and outer radius d. The inner shell has total charge +2q, and the outer shell has charge +4q. (a) Calculate the magnitude of the electric field in terms of q and the distance r from the common center of the two shells for r < a, b < r < c, and r > d. Note...
A
smooth spherical shell of electricity insulating material with
outer radius a and inner radius a/2. Inside of this sphere, also
with a radius of a/2, is a conducting solid sphere. The conducting
sphere has an excess amount of charge q. The density of the
insulating sphere is p.
A)
What must be the value of p so that the total charge of this setup
is 0?
B)
Using the value of p from part (A), what are the magnitude...
In the figure the sphere of radius R is solid and non-conductive and has a uniform charge volumetric distribution p0. A spherical shell with inner radius 2R and outer radius 3R is concentric with the sphere and unloaded. Find, in terms of p0 and R: a) the value of the electric charge in the sphere, b) the magnitude of the electric field at a radial distance r - 2.5R, c) the value of the surface charge density induced in the...
Please show work for all parts, thank you.
Course Contents> ... > Assignment #3: Gauss' Law » 23-49 Electric field of a solid sphere concentric with a < Timer Notes Evaluate Feedback Print Info In the figure, a solid sphere of radius a = 8.6 cm is concentric with a spherical conducting shell of inner radius b = 20.6 cm and outer radius c = 22.6 cm. The sphere has a net uniform charge 41 = 6.00x10- C. The shell...
Guided Problem 4 -Gauss's LawA solid, insulating sphere of radius a has a uniform charge density ρ and a total charge Q. Concentric with this sphere is an uncharged, conducting hollow sphere whose inner and outer radii are b and c as shown in the following figure. (a) Find the magnitude of the electric field in the regions: r<a, a<r<b, and r>c. (b) Determine the induced charge per unit area on the inner and outer surfaces of the hollow sphere.Solution scheme:...
2. A positive point charge +Q resides at the center of a conducting spherical shell of inner radius R1, of outer radius R2, and of total charge -4Q. Use Gauss's law to find the charge on: (a) the inner surface at r=R1 and (b) the outer surface at r=R2. Find the magnitude and direction of the electricfield at a distance r from the point charge: (c) for r<R1,(d) for R1<r<R2, and (e) for r>R2. Draw a diagram showing all charges...