Find the electric field strength inside a solid sphere.

AI Thread Summary
To find the electric field strength inside a solid sphere with a radius of 25 cm and a uniform charge of 14 µC, it is essential to use Gauss's Law rather than the formula E = (kq)/r^2. The charge density can be calculated as p = q/volume, leading to a density of approximately 2.14 × 10^-4 C/m^3. For distances less than the sphere's radius, such as 15 cm, the enclosed charge must be determined using the volume of the Gaussian surface, which is not the total charge of the sphere. The enclosed charge at 15 cm can then be used to find the electric field strength, which differs from the values calculated at the surface and outside the sphere. Understanding the application of Gauss's Law is crucial for accurately determining the electric field inside the sphere.
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Homework Statement


A solid sphere 25cm in radius carries 14uC, distributed uniformly throughout its volume. Find the electric field strength (a.) 15cm, (b.) 25cm, (c.) 50cm from the sphere's center.

R = .25m
Q = 14 * 10^-6 C

Homework Equations


p = q/(volume)
E = (kq)/r^2


The Attempt at a Solution


a.) I have absolutely no idea where to even begin here. This is what I really need help with. I'm not sure if the answer relates to the other two distances, so i'll show how I got those. For some reason, E = (kq)/r^2 fails here.

b.) E = (kq)/r^2 = (9.0*10^9 Nm^2/C^2)(14*10^-6 C)/(.25m)^2 = 2.02 * 10^-6 N/C

c.) E = (kq)/r^2 = (9.0*10^9 Nm^2/C^2)(14*10^-6 C)/(.50m)^2 = 504 * 10^3 N/C
 
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The field inside a uniformly charged sphere is not kq/r^2. To determine the actual relationship, the easiest way is to use Gauss's Law. Are you familiar with Gauss's law?
 
gabbagabbahey said:
The field inside a uniformly charged sphere is not kq/r^2. To determine the actual relationship, the easiest way is to use Gauss's Law. Are you familiar with Gauss's law?

Yes I am familiar with Gauss's Law.

flux = integral(EAcos(theta)) = q_enclosed/e_0.

I'm still not sure where to go from here, though.
 
What is Q_{enclosed} at r= 15cm?
 
gabbagabbahey said:
What is Q_{enclosed} at r= 15cm?

I know its not 14uC. It must be something else, but I can't seem to figure out what.

Q = (e_0)*E*A ?

A = 4(pi)r^2 = 4(pi)(.15m)^2 = .2827m^2 ?
 
Well the 14uC is distributed uniformly throughout the sphere, so what is the charge density of the sphere then?
 
I would say Q/A = 14*10^-6 C * .2827 m^2 = 5*10^-5 C/m^2

But plugging that into: E = (5*10^-5 C/m^2)/e_0 = 5.59*10^6 N/C.

But my book says E = 1.21 MN/C
 
Last edited:
Can anyone point me in the right direction here?

I still can't wrap my head around this. :(If the charge density is p = q/volume. Then p = (14*10^-6 C)/(4/3*pi*(.25m)^2 = 2.14*10^-4 C/m^3

But how do I use this?
 
Well, Q_{enclosed} is the charge enclosed by your Gaussian surface. For part (a), the Gaussian surface does not enclose the entire volume; and so it does not enclose the entire charge. What volume is enclosed for r=15cm? Shouldn't the charge enclosed be that volume times the density that you just calculated?
 

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