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Electric field outside of a current carrying wire 
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#1
Sep2410, 02:13 PM

P: 217

Hello,
Basically my problem is trying to understand the electric field outside of a current carrying wire. My first thought is that it is zero, but now I am not sure. The boundary condition of the electric field says that the parallel component inside and out must be the same, so this means the the electric field is nonzero just outside the wire. But if that were the case, then some current could go outside the wire right? Help me with my concept here, thanks. 1. The problem statement, all variables and given/known data The question is about finding the poyting vector inside and outside of a current carrying wire. I am stuck on the electric field outside the wire. 2. Relevant equations 3. The attempt at a solution 


#2
Sep2410, 03:23 PM

P: 799

Taking a highly symmetrical example as a cylindrical uniform wire, it's easy to see that that parallel component is zero due to symmetry, regardless of whether the wire is electrically neutral or not. If you force the electrons to flow in a weird way, there might be some chances that Efield also exists outside the wire. But I don't think it's practical or significant. Just my 2cents 


#3
Sep2410, 04:00 PM

P: 217

Well, there must be a component of the E field parallel to the wire inside the wire right? Otherwise there would be no current. Then the boundary condition at the edge of the wire says that the E field outside the wire also has a parallel component.



#4
Sep2510, 01:30 AM

P: 799

Electric field outside of a current carrying wire
Yep, you're right. I was hasty back then.
After giving it a thought, my best guess is there is always Efield outside the conductor. The parallel component at the surface remains the same: [tex]E_{pout}=E_{pin}[/tex] Therefore: [tex]\frac{J_{pout}}{\rho _{out}}=\frac{J_{pin}}{\rho _{in}}[/tex] Since [tex]\rho _{out} >> \rho _{in}[/tex] and [tex]J_{pin}[/tex] is finite, we have [tex]J_{pout} \approx 0[/tex]. The discontinuity in normal component at the surface: Consider the case of steady state. At steady state: [tex]div\vec{J}=0[/tex] Thus: [tex]J_{nout}=J_{nin}[/tex] Or: [tex]\frac{E_{nout}}{\rho _{out}}=\frac{E_{nin}}{\rho _{in}}[/tex] (*) When [tex]\rho _{out} >> \rho _{in}[/tex] the current is almost retained inside the conductor, i.e. [tex]J_{n} \approx 0[/tex] or [tex]E_{nin} \approx 0[/tex] as [tex]\rho _{in}[/tex] is finite. However, as [tex]\rho _{out}[/tex] is relatively large, from equation (*), we can see that no conclusion can be drawn about the magnitude of [tex]E_{nout}[/tex]. In highly symmetrical cases such as cylindrical uniform neutral wire, by Gauss's law, we can easily see that [tex]E_{nout}=0[/tex]. But in general, [tex]E_{nout}\neq 0[/tex], which leads to a fact that there is charges on the surface of the conductor. 


#5
Oct1110, 07:34 AM

P: 15

your question is very much my question.
i expect that the electric field outside a current carrying(regardless of whether the current is steady or unsteady) must NOT be zero. this is because... let's assume the contrary... i.e. let's assume that there is no electric field outside a current carrying wire. now, the wire has some resistance. take two distince points inside the wire say A & B. now ohm's law says that there is a potential difference between A & B. call that potential differnce = V. for simplicity, assume charge density at any given point does not change. this also implies steady current. now V = line integral of electric field along ANY path joining A & B.( since in case of rho=const curl of E is zero) if the path lies completely inside the wire then there is no trouble since we know that there is electric field inside the wire which is responsible for creating the potential difference. BUT. if the path( or part of that path) lies outside the connecting wire( i dont think that there is any restriction in choosing such a path) then since we had assumed that there was no field outside the wire, the potential difference between A & B would be ZERO(or at least less than V for sure). this would be a contradiction. the only possibility is that there should be electric field present outside a current carrying wire.) 


#6
Jan1211, 09:43 AM

P: 10

Many theorists believe that there can’t be any Electric Field outside a current carrying wire and their main argument is based on the assumption that the wire is neutral electrically.
Although the wire has no net charge as a whole, the charge density on the surface is not constant (in fact it varies linearly along the wire)! This distribution produces not only an internal Electric Field of constant magnitude (which drifts the elections), but also an external Field of some kind. In the extreme case of a perfect conductor all Electric Fields vanish, so any closedline integral of the electric intensity is again zero. 


#7
Jan1211, 11:41 AM

P: 15

to argue in favour of this consider a wire carrying CONSTANT CURRENT. its easy to see that the charge density inside the wire at any point is zero as div(E)=k*div(J) now div(E) is proportioanl to charge density and div(J) is zero as the current is steady as assumed. so div(E) is zero and hence charge density everywhere inside the wire is zero. this, however, cannot be said for the SURFACE of the wire as div(J) really does not exist there. let's assume that the surface charge density at the surface of the wire is also zero. now,we know that there is electric field present inside the wire(ohm's law). what is the cause of this electric field? there is no varying magnetic field present here as the currents are steady. there are no charge densities present anywhere since we have assumed that surface charge density is zero and we have proved that charge density inside the wire was zero. then what is the cause of the electric field? varying magnetic field no, charge densities no. then what?? well, this means that the assumption that the surface charge density is zero at the surface is WRONG. what say papikoss?? 


#8
Jan1211, 12:12 PM

P: 10

I think that your arguments are solid and can only lead to the conclusion that there must be some kind of surface charge distribution producing the Electric Field within and outside the wire.
In fact such a distribution exists indeed and, as I mentioned above, it varies linearly along the path of the wire. The role of the battery is to sustain those surface free charges. This is a subject not much covered by modern textbooks but you can find some very interesting information if you google these: 1) Surface Charges on Conductors Carrying Steady Currents by B. R. Russell 2) The Electric Field Outside a Stationary Resistive Wire Carrying a Constant Current by A. K. T. Assis, W. A. Rodrigues Jr., and A. J. Mania. 3) Static Surface Charge on CurrentCarrying Conductors by R. Cade and D. Soto Bello (haven't read that yet) 


#9
Jan1611, 07:38 PM

P: 15

thank u so much papikoss. that was great help. :)



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