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Using Gauss's law obtain the expression ...

Using Gauss's law obtain the expression for the electric field due to uniformly charged thin spherical shell of radius R at a point outside the shell. Draw a graph showing the variation of electric tield with r, for r gt R and r lt R.

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To find the expression for the electric field due to a uniformly charged thin spherical shell at a point outside the shell using Gauss's law, we can follow these steps: ### Step 1: Understanding the Setup Consider a uniformly charged thin spherical shell of radius \( R \) with a total charge \( Q \). We want to find the electric field at a point \( P \) located at a distance \( r \) from the center of the shell, where \( r > R \). ### Step 2: Choosing a Gaussian Surface To apply Gauss's law, we choose a Gaussian surface that is a sphere of radius \( r \) (where \( r > R \)) centered at the same center as the spherical shell. This surface will help us calculate the electric field due to the charge enclosed. ...
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Knowledge Check

  • The electrostatic potential of a uniformly charged thin spherical shell of charge Q and radius R at a distance r from the centre

    A
    `(Q)/(4 pi epsilon_(0)r)` for points outside and `(Q)/(4pi epsilon_(0)R)` for points inside the shell
    B
    `(Q)/(4pi epsilon_(0)e)` for both points inside nad outside the shell
    C
    zero for points outside and `(Q)/(4pi epsilon_(0)r)` for points inside the shell
    D
    zero for both points inside and outside the shell

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