Energy in 10 m of Cable: Calculating Voltage Storage

AI Thread Summary
The discussion focuses on calculating the energy stored in a 10-meter coaxial cable with specific dimensions and dielectric material. Participants clarify the correct formula for energy storage, emphasizing that it should be U = 0.5 * C * V^2, where C is the capacitance. They highlight the importance of determining charge per unit length using Gauss' law and integrating the electric field to find voltage. The confusion arises around the relationship between charge, voltage, and energy, ultimately resolving that the correct energy formula is based on capacitance. The thread concludes with a consensus on the correct approach to the problem.
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Homework Statement


The diagram below depicts a cross section of coaxial conductor with an inner wire of diameter and an outer conducting sheath of inside diameter , and some material placed in the space between the two wires. Suppose that you have a coaxial wire with di= 2.85 mm, do= 6.25 mm and mylar ( k= 3.10) is placed in the space between the two wires. If there is a potential of 1 kV between the wires, how much energy is stored in a 10 m piece of cable?

Homework Equations



U=\int V dQ

The Attempt at a Solution


I perform the intergral and come up with a couple equations this one seem the best:
U= .5QV Right?
 

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How did you get 0.5QV ?

The way I'd do it is to find the charge per unit length on the inner wire... the charge per unit length on the outer conductor is just - the inner charge per unit length...

You can get this using Gauss' law... and the voltage = -integral E.dr

When you find the charge per unit length x... then the total charge is 10*x. The energy stored is 10*x*V.
 
You need to know the charge right? Or how charge varies with voltage or something?
 
The coax cable has capacitance per meter. You can look the equations up on wiki. Once you find the total capacitance (multiply by length), use E=(CV^2)/2.



Sterling
 
learningphysics said:
How did you get 0.5QV ?

The way I'd do it is to find the charge per unit length on the inner wire... the charge per unit length on the outer conductor is just - the inner charge per unit length...

You can get this using Gauss' law... and the voltage = -integral E.dr

When you find the charge per unit length x... then the total charge is 10*x. The energy stored is 10*x*V.

I do not know what I am doing wrong. Here is my work:
q/(кε) = EA, A = 2*pi*rx
E = q/(кεA) = q/(2кε*pi*rx)
V = -integral of Edr from a to b = -(q*ln(b/a))/(2кε*pi*x) = 1000 V
1000(2кε*pi)/ln(b/a) = q/x
(q/x)*10*1000 does not give me the answer. Where did I go wrong?
 
Thanks. It turns out my work is right, but the formula for energy is .5qV (i.e. C = q/V, so .5CV^2 = .5qV) , not qV.
 

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