Hello 12x4,
Welcome to PF! :)
12x4 said:
Homework Statement
:
Co-axial cable, relative permittivity, capacitance, internal energy
A long straight co-axial cable of length 1 consists of an inner conductor of radius r
1 and a thin outer conductor or radius r
2. The dielectric between the conductors has a relative permittivity ε
r.
[/B]
- (a) Find the strength of the electric field E(r) between the conductors (r1 < r < r2) for equal and opposite charges ±Q on the conductors.
- (b) Calculate the total potential difference V between the conductors if they were to carry equal and opposite charges ±Q.
Homework Equations
:[/B]
Gauss' Law ∫E.ndA = Q/ε
r
Just a note on your version of the equation: In my experience, it is conventional to express the overall permittivity \varepsilon as
\varepsilon = \varepsilon_0 \varepsilon_r
where \varepsilon_0 is the permittivity of free space and where \varepsilon_r is the relative permittivity. The relative permittivity is greater than or equal to 1: being 1 for a vacuum, and greater than 1 for dielectrics.*
*[Edit: Actually, it can be more complicated than that. \varepsilon_r can be a function of frequency, and might even take on complex values. But that's more than what we need to worry about here. For now just treat it is a real number, greater than or equal to 1.]
I wanted to point this out, because your notation is different from the convention that I've found to be most common. In the convention that I'm used to, you'll still need to throw an \varepsilon_0 in there somewhere [Edit: together with \varepsilon_r]. I suggest checking the conventions of your textbook/coursework before continuing, to make sure we're all on the same page regarding the notation.
Um, shouldn't that be \Delta V = -\int_a^b \vec E \cdot \vec {d \ell} ?
As in \Delta V = V_b - V_a?
I fear leaving the left hand side in differential form (i.e., "dV") is not the right way to put it. It should be "Delta" V. The left hand side of the equation is the potential difference ("difference" as in subtraction of [possibly] large quantities,
not an infinitesimal change in potential).
The Attempt at a Solution
:
Part a)[/B]
I'm not sure if I'm being really stupid here but are you able to work this question out like this? first find the electric field produced at the inner and outer surface of the outer and inner conductors respectively and then sum them together?:
It's difficult to give a yes/no answer on this question. Technically the answer is 'yes', but probably not the way you are thinking. More on this below.
I'll repeat this below, but remember, the 'Q' in Gauss' law is the charge enclosed
within the Gaussian surface.
for the inner cable:
∫E.ndA = Q/εr ⇒ E(2πr1l)=Q/εr ⇒ (l=1) ⇒ E = Q/2πr1εr
The electric field in between the two conductors is not constant. By that I mean sure, the electric field is constant on the Gaussian surface for a given radius
r, but it is not constant as
r changes. Your expression for the electric field between r_1 and r_2
should be a function of r.
I'll stop you here on this part. Rethink the meaning of Gauss' law for a cylinder. If you removed the center conductor and all of its charge, what would the electric field be within a long, hollow, charged cylinder?
[...snip...]
Part B)
To complete this part of the question surely i need my expression for a) to be in terms of an arbitrary value r rather than r1 and r2. Any help would be hugely appreciated as I've been going round in circles with this for a while now.
You are correct that the electric field between r_1 and r_2
should be a function of r. Write a general expression for Gauss' law somewhere between r_1 and r_2. The expression should be a function of r, not r_1.
Once you have that, you can use your other equation in your "relevant equations" section to get the potential.
