Answer: 0 (Zero)
According to Gauss's Law : Net electric flux through the Gaussian surface = Qenclosed / ε0
If we consider inner surface as a Gaussian surface, then the charge enclosed by that surface will be equal to Zero.
Therefore, Net flux through the inner surface will be ZERO.
A charge Q is distributed uniformly throughout a spherical insulating shell. The net electric flux in...
A spherical shell with a charge of 3.8 µC uniformly distributed throughout the shell has an inner surface with radius of 4.0 cm and outer surface with radius of 5.0 cm. Use Gauss’s Law to find the electric field a. 1.0 cm from the inner surface, inside the shell. b. halfway between the two surfaces. c. 5.0 cm from the outer surface, outside the shell.
#1 and #3
I) )A solid insulating sphere of radius a carries a net positive charge density 3p uniformly distributed throughout its volume. A conducting spherical shell of inner radius 2a and outer radius 3a is concentric with the solid sphere and carries a net charge density-22 Using Gauss's law, find the electric field everywhere. Sketch the electric field 2) "A) The current density in a cylindrical wire of radius R meters is uniform across a cross section of the...
A charge Q is distributed uniformly on the surface of a spherical conducting shell of radius 10 cm. The magnitude of electric field on the surface is 106V/m. What is the magnitude of electric field 20 cm from the center of the shell? What is the surface charge density in Cm2 of the spherical shell in problem 4?
5. A thick, nonconducting spherical shell with a total charge of Q distributed uniformly has an inner radius R1 and an outer radius R2. Calculate the resulting electric field in the three regions r<RI, RL<r<R2, and r > R2
A total charge of Q=7.33 μC is evenly distributed throughout a plastic spherical shell with an inner radius of r1=0.199 m and an outer radius of r2=0.581 m.. The shell is centered at the origin (xc=0, yc=0, zc=0). Calculate the magnitude of the electric field at the location (x=0 m, y=0 m, z=2.57 m). The answer is in N/C.
insulating sphere of radius a carries a positive charge 3Q, uniformly distributed its volume. Concentric with this sphere a conducting spherical shell with inner radius b and outer radius c, and having a net charge -Q as shown in Figure. Find the charge distribution on the shell (charge on the inner radius b and charge on the outer radius c) when entire system is in electrostatic equilibrium.
A solid insulating sphere of radius a = 0.3 m, carries a total charge Q = 225 pc distributed uniformly throughout its volume. Find the electric flux (in Nm/C), through a concentric Gaussian spherical surface of radius r = 0.2 m, as shown in the figure. Gaussian sphere Select one: a. 85.81 b. 7.54 c. 25.43 d. 15.01 e. 50.62
Consider a thick spherical
conducting shell with NO net charge. A point charge +Q is placed at
its center as shown in the figure.
True or False for the following statements.
1) The electric field at c is zero.
2) The electric field at e is zero.
3) The inner surface of the shell carries a charge -Q.
4) The electric field at a is zero.
(please show work! thanks!)
A solid insulating sphere of radius a carries a net positive charge +2Q, uniformity distributed throughout its volume. Concentric with this sphere is a conducting spherical shell with inner radius b and outer radius c, having a net charge of -3Q. Let the variable r represent the radial variable defined from the center of the sphere to an arbitrary point of interest defined by the following questions. A) Derive an expression for the electric field only in terms of the...
A charge of q-+ 10.7 C is uniformly distributed on a spherical shell of radius 18 cm. (a) What is the magnitude of the electric field just outside and just inside the shell? kV/m (outside) kV/m (inside) (b) What is the magnitude of the electric potential just outside and just inside the shell? V (outside) V (inside) (c) What is the electric potential at the center of the shell? What is the electric field at that point? kV/m