Let's say I have a uniformly charged wire with some constant linear charge density. Along a line parallel to the $z$-axis and passing through $(0,y,0)$ and asked to find an electric field at a point $(p,q,r)$. Then the vector should be $p \textbf{i} +(q-y)\textbf{j}+r\textbf{k}$. My books say the field has no $z$ component and it takes vector as $p\textbf{i}+(q-y)\textbf{j}$. Can someone explain this?
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Simplify the problem considering as infinite straight line with constant linear charge density $:\lambda:$ the $:x-$axis. You have then rotational symmetry with respect to this axis. The method of solution depends on what are you studying : Coulomb Law or Gauss Law. – Frobenius Aug 14 '22 at 18:30
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Related : Why don't stationary charge feel force from a current carrying wire?, Figure-03. – Frobenius Aug 14 '22 at 18:32
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It is a question of symmetry. If the source (charge distribution) is z independent (the same for any z), then the field does not depend on z.
It can be mathematically proven, but a simple drawing is sufficient.
Consider two elementary segment of length $ dl_{1}$and$ dl_{2}$. They carry the charge $ dq= \lambda dl_{1}= \lambda dl_{2} $ This charges create at the M two electric fields:$ \overrightarrow{d E_{1} } $ and $ \overrightarrow{d E_{2} } $. The electric field intensity only depends on the charge and distance between source and point of observation. So $d E_{1}=d E_{2}=dE= \frac{dq}{4 \pi \varepsilon _{0} r^{2} }$ At the point of observation, the electric fields add up. The vertical components cancel out and one gets: $ \overrightarrow{dE} =2.cos( \theta )dE \overrightarrow{i} $
Shaktyai
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hi, thanks for explanation. But I didn't get it. Can you explain about the drawing and if you can provide any link to the mathematical proof that will be very useful for me. – Sai Aug 14 '22 at 18:55
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