91影视

V is the electric potential, q is the charge and r is the distance

$$\begin{gathered} V=\frac{1/\left(4蟺{蔚}_0\right)q}{r} \\ {蔚}_0=8.85脳{10}^{-12}{C}^2/N脳m^2 \end{gathered}$$

On the basis of the figure

the two charges are -2.0nC and 2.0nC on the X axis position is x= -0.1 cm and +0.1cm

and q value from nano columb to coulomb is $2.0脳{10}^{-9}C$

(a)

When x is greater than 1 then the potential charge is larger and direction is positive but negative charge is smaller. both positive and negative direction is $\stackrel{炉}{x}$. due to this reason, there is no region and E = 0 at this position.

When x is belonged into $-1<x>+1$then the both direction is same and summation of the two points is zero.

Due to this reason, the electric field is zero and position is zero.

The charge value at the midpoint for the charge $q_1$and V is the potential energy.

The charge value at the midpoint for the charge $q_1$

$V_1=\frac{k{q}_1}{r}$

The charge value at the midpoint for the charge $q_2$

$V_2=\frac{-k{q}_2}{r}$

The net charge is equal to the summation of the two charge

$\begin{array}{rcl}V& =& V_1+V_2\\ & =& \frac{k{q}_1}{r}+(-\frac{k{q}_2}{r})\\ & =& 0V\end{array}$

From the equation, there is a region but the electric field is zero. So the net potential at the midpoint is zero.

As when the x > +1.0cm

Applying the given data

$$\begin{gathered} V=\underset{i}{鈭�}1/\left(4蟺{蔚}_0\right)q\left(\frac{q_1}{r_{x=+1.0cm}}+\frac{q_2}{r_{x=-1.0cm}}\right) \\ =2.0脳{10}^{-9}C/\left(4蟺{蔚}_0\right)\left(\frac{1}{x-1}-\frac{1}{x+1}\right) \end{gathered}$$

As when the x > -1.0cm

$\begin{array}{rcl}V& =& \underset{i}{鈭�}1/\left(4蟺{蔚}_0\right)q_i/r_i\\ V& =& \underset{i}{鈭�}1/\left(4蟺{蔚}_0\right)q\left(\frac{q_1}{r_{x=+1.0cm}}+\frac{q_2}{r_{x=-1.0cm}}\right)\\ q_1& =& 2.0脳{10}^{-9}C\\ q_2& =& -2.0脳{10}^{-9}{C}^{}\\ & & r_{x=+1.0cm}\\ & =& x+1\\ & & r_{x=-1.0cm}\\ & =& x-1\end{array}$

Applying the given data

$\begin{array}{rcl}V& =& \underset{i}{鈭�}1/\left(4蟺{蔚}_0\right)q\left(\frac{q_1}{r_{x=+1.0cm}}+\frac{q_2}{r_{x=-1.0cm}}\right)\\ & =& 2.0脳{10}^{-9}C/\left(4蟺{蔚}_0\right)\left(\frac{1}{x+1}+\frac{1}{1-x}\right)\\ & & \\ & & \end{array}$

As when the -1.0cm< x < +1.0cm

$$\begin{gathered} V=\underset{i}{鈭�}1/\left(4蟺{蔚}_0\right)q_i/r_i \\ V=\underset{i}{鈭�}1/\left(4蟺{蔚}_0\right)q\left(\frac{q_1}{r_{x=+1.0cm}}+\frac{q_2}{r_{x=-1.0cm}}\right) \\ {q}_1=2.0脳{10}^{-9}C \\ {q}_2=-2.0脳{10}^{-9}C \\ {r}_{x=+1.0cm}=1-x \\ {r}_{x=-1.0cm}=x+1 \end{gathered}$$

Applying the given data

$$\begin{gathered} V=\underset{i}{鈭�}1/\left(4蟺{蔚}_0\right)q\left(\frac{q_1}{r_{x=+1.0cm}}+\frac{q_2}{r_{x=-1.0cm}}\right) \\ =2.0脳{10}^{-9}C/\left(4蟺{蔚}_0\right)\left(\frac{1}{1-x}+\frac{1}{x+1}\right) \end{gathered}$$

As when the x > +1 cm. Assume a point that has distance from origin at x distance

$\begin{array}{rcl}E& =& \underset{i}{鈭�}1/\left(4蟺{蔚}_0\right)q_i/{r^2}_i\\ & & \\ E& =& \underset{i}{鈭�}1/\left(4蟺{蔚}_0\right)q\left(\frac{q_1}{{r_{x=+1.0cm}}^2}+\frac{q_2}{{r_{x=-1.0cm}}^2}\right)\\ q_1& =& 2.0脳{10}^{-9}C\\ q_2& =& -2.0脳{10}^{-9}C\\ r_{x=+1.0cm}& =& x-1\\ r_{x=-1.0cm}& =& x+1\end{array}$

Applying the given data

$E=2.0脳{10}^{-9}C/\left(4蟺{蔚}_0\right)\left(\frac{1}{{\left(x-1\right)}^2}-\frac{1}{{\left(x+1\right)}^2}\right)$

As when the x < -1 cm. Assume a point that has from origin at x distance

$\begin{array}{rcl}E& =& \underset{i}{鈭�}1/\left(4蟺{蔚}_0\right)q_i/{r^2}_i\\ E& =& \underset{i}{鈭�}1/\left(4蟺{蔚}_0\right)q\left(\frac{q_1}{{r_{x=+1.0cm}}^2}+\frac{q_2}{{r_{x=-1.0cm}}^2}\right)\\ q_1& =& 2.0脳{10}^{-9}C\\ q_2& =& -2.0脳{10}^{-9}C\\ r_{x=+1.0cm}& =& x+1\\ r_{x=-1.0cm}& =& x-1\end{array}$

Applying the given data

$E=2.0脳{10}^{-9}C/\left(4蟺{蔚}_0\right)\left(\frac{1}{{\left(x+1\right)}^2}+\frac{1}{{\left(1-x\right)}^2}\right)$

As when the -1<x < +1 cm. Assume a point that has distance from origin at x distance

$$\begin{gathered} E=\underset{i}{鈭�}1/\left(4蟺{蔚}_0\right)q_i/{r^2}_i \\ E=\underset{i}{鈭�}1/\left(4蟺{蔚}_0\right)q\left(\frac{q_1}{{r_{x=+1.0cm}}^2}+\frac{q_2}{{r_{x=-1.0cm}}^2}\right) \\ {q}_1=2.0脳{10}^{-9}C \\ {q}_2=-2.0脳{10}^{-9}C \\ {r}_{x=+1.0cm}=1-x \\ {r}_{x=-1.0cm}=x+1 \end{gathered}$$

Applying the given data

$E=2.0脳{10}^{-9}C/\left(4蟺{蔚}_0\right)脳\left(\frac{1}{{\left(1-x\right)}^2}+\frac{1}{{\left(1+x\right)}^2}\right)$