Determining Charge Density of Nonconducting Sphere

jackxxny
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Homework Statement


i have:
a nonconducting sphere of radius 25 cm. the electric field points radially away from the center of the sphere, and increase linearly from 0 to 3700V/m at the surface of the sphere.
determine charge density?

Homework Equations



i think the E=E0+r*148

The Attempt at a Solution



so i did [tex]\int E *da = \int p(r) d \tau / \epsilon0[/tex]

then i substitute E

[tex]da = 4* pi * r^{2}<br /> [/tex]

[tex] d \tau = 4* pi * r^{2} dr[/tex]then i simplify for p(r)is that right?
 
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Yes. It is right.
 
thank you
 
i got


p(r) = [tex]\epsilon 0 *(E_{}o 2/r +3)[/tex]

can that be?

and now the problem is asking for the potential difference between the center and the surface of the sphere

i know that

[tex]\Delta V = -\int E dr[/tex]

will that do it??
 
p(r) = [tex]\epsilon 0 *(E_{}o 2/r +3)[/tex]
How did you get this one?
Your formula for dV is correct.
 
[tex] (Eo+r*148)*( 4* pi * r^{2})* \epsilon 0 = \int p(r) (4*pi*r^{2}) dr<br /> <br /> [/tex]


then i take the derivative on both sides and isolate p(r)

i obtain =

[tex] \epsilon 0*(E0*2/r +396) = p(r)<br /> [/tex]
 
i got -15000 for the potential. I consider Eo to be zero is that a good assumption?
 
think the E=E0+r*148
Is it given in the problem?
 
no. I thought since the problem said that it is linearly that might work?
 
  • #10
No. It is not correct.
Electric field is given.
You have found E = ρ*r/εο. Find ρ.
Now dV = - dE*dr To find the potential V on the surface find the integration.
 
  • #11
..."the electric field points radially away from the center of the sphere, and increase linearly from 0 to 3700V/m at the surface of the sphere."

- this means that E=0 at the centre of the sphere and E=Es=3700 V/m at the surface, and increases linearly inside the sphere from r=0 to r=R, the radius of the sphere.
The enclosed charge in the sphere is
[tex]Q=4/3 R^3 \pi \rho[/tex] and by Gauss' Law, [tex]Q=4R^2 \pi \epsilon_0 E_s[/tex]. Comparing the equations for the total charge, you get the charge density.
As for the potential at the surface of the sphere: remember that we usually choose zero potential at infinity, and outside a homogeneously charged sphere the electric field is the same as that of a point charge...

ehild
 
  • #12
[tex] 4/3 R^3 \pi \rho = 4R^2 \pi \epsilon_0 E_s [/tex]

so i just set it equal to each other and solve for p


[tex] \rho = 3 \epsilon_0 E_s / R [/tex]

is that it?
 
  • #13
Yes. Now calculate it with the given data.

ehild
 
  • #14
ok i got the charge density


how do i do the potential


so how do i do this integral

dV = - dE*dr
 
  • #15
Previously you have written the integral correctly:


[tex] \Delta V = -\int E dr[/tex]

You want the potential at the surface of the sphere and you know that it is nought at infinity:

[tex] \Delta V= V(\infty)-V(R) = -\int_R^\infty{ E dr}[/tex]

You certainly have learned that the electric field outside a homogeneously charged sphere is the same as if its total charge were concentrated in the centre. What is the field around a point charge?

[tex] <br /> E=\frac{1}{4\pi\epsilon_0}\frac{Q}{r^2}<br /> [/tex],

is it right? You know Q, the total charge of the sphere.

Now integrate this formula for E.

ehild
 

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