Calculate the formula of electric field due to a long charges wire without using gauss law "easybmeathod"
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Let us draw a cylindrical gaussian surface, co-axial with the wire, of radius $R$ and length $L$--see Fig. 11. The above symmetry arguments imply that the electric field generated by the wire is everywhere perpendicular to the curved surface of the cylinder. Thus, according to Gauss' law,
\begin{displaymath}
E(R)\,2\pi \,R\, L = \frac{\lambda\, L}{\epsilon_0},
\end{displaymath} (70)
where $E(R)$ is the electric field-strength a perpendicular distance $R$ from the wire. Here, the left-hand side represents the electric flux through the gaussian surface. Note that there is no contribution from the two flat ends of the cylinder, since the field is parallel to the surface there. The right-hand side represents the total charge enclosed by the cylinder, divided by $\epsilon_0$. It follows that
\begin{displaymath}
E(R) = \frac{\lambda}{2\pi\epsilon_0\,R}.
\end{displaymath} (71)
The field points radially (in a cylindrical sense) away from the wire if $\lambda>0$, and radially towards the wire if $\lambda<0$.
\begin{displaymath}
E(R)\,2\pi \,R\, L = \frac{\lambda\, L}{\epsilon_0},
\end{displaymath} (70)
where $E(R)$ is the electric field-strength a perpendicular distance $R$ from the wire. Here, the left-hand side represents the electric flux through the gaussian surface. Note that there is no contribution from the two flat ends of the cylinder, since the field is parallel to the surface there. The right-hand side represents the total charge enclosed by the cylinder, divided by $\epsilon_0$. It follows that
\begin{displaymath}
E(R) = \frac{\lambda}{2\pi\epsilon_0\,R}.
\end{displaymath} (71)
The field points radially (in a cylindrical sense) away from the wire if $\lambda>0$, and radially towards the wire if $\lambda<0$.
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