(a) (i) The point $O$ is equidistant from all the charges at the end point of pentagon. Thus, due to symmetry, the forces due to all the charges are cancelled out. As a result electric field at $O$ is zero.

(ii) When charge $q$ is removed a negative charge will develop at $A$ giving electric field $E=\frac{q \times 1}{4 \pi \varepsilon_0 r^2}$ along $O A$.

(iii) If charge $q$ at $A$ is replaced by $-q$, then two negative charges $-2 q$ will develop there. Thus, the value of electric field $E=\frac{2 q}{4 \pi \varepsilon_0 r^2}$ along $O A$.

(b) When pentagon is replaced by $n$ sided regular polygon with charge $q$ at each of its corners, the electric field at $O$ would continue to be zero as symmetricity of the charges is due to the regularity of the polygon. It doesn't depend on the number of sides or the number of charges.

(a) Let us suppose that universe is a perfect sphere of radius $R$ and its constituent hydrogen atoms are distributed uniformly in the sphere.

As hydrogen atom contains one proton and one electron, charge on each hydrogen atom.

$$e_H=e_P+e=-(1+Y) e+e=-Y e=(Y e)$$

If $E$ is electric field intensity at distance $R$, on the surface of the sphere, then according to Gauss' theorem,

$$\begin{aligned} \oint \text { E.ds } & =\frac{q}{\varepsilon_0} \text { i.e., } E\left(4 \pi R^2\right)=\frac{4}{3} \frac{\pi R^3 N \mid Y_{e \mid}}{\varepsilon_0} \\ E & =\frac{1}{3} \frac{N|Y e| R}{\varepsilon_0}\quad\text{... (i)} \end{aligned}$$

Now, suppose, mass of each hydrogen atom $\simeq m_P=$ Mass of a proton, $G_R=$ gravitational field at distance $R$ on the sphere.

$$\begin{aligned} \text{Then,}\quad-4 \pi R^2 G_R & =4 \pi G m_P\left(\frac{4}{3} \pi R^3\right) N \\ \Rightarrow\quad G_R & =\frac{-4}{3} \pi G m_P N R\quad\text{.... (ii)} \end{aligned}$$

$\therefore$ Gravitational force on this atom is $F_G=m_P \times G_R=\frac{-4 \pi}{3} G m_P^2 N R\quad\text{.... (iii)}$

Coulomb force on hydrogen atom at $R$ is $F_C=(Y e) E=\frac{1}{3} \frac{N Y^2 e^2 R}{\varepsilon_0}\quad$ [from Eq. (i)]

Now, to start expansion $F_C>F_G$ and critical value of $Y$ to start expansion would be when

$$\begin{aligned} F_C & =F_G \\ \Rightarrow \quad \frac{1}{3} \frac{N Y^2 e^2 R}{\varepsilon_0} & =\frac{4 \pi}{3} G m_P^2 N R \\ \Rightarrow \quad Y^2 & =\left(4 \pi \varepsilon_0\right) G\left(\frac{m_P}{e}\right)^2 \\ & =\frac{1}{9 \times 10^9} \times\left(6.67 \times 10^{-11}\right)\left(\frac{\left(1.66 \times 10^{-27}\right)^2}{\left(1.6 \times 10^{-19}\right)^2}\right)=79.8 \times 10^{-38} \\ \Rightarrow \quad Y & =\sqrt{79.8 \times 10^{-38}}=8.9 \times 10^{-19} \simeq 10^{-18} \end{aligned}$$

Thus, $10^{-18}$ is the required critical value of $Y$ corresponding to which expansion of universe would start.

(b) Net force experience by the hydrogen atom is given by

$$F=F_C-F_G=\frac{1}{3} \frac{N Y^2 e^2 R}{\varepsilon_0}-\frac{4 \pi}{3} G m_P^2 N R$$

If acceleration of hydrogen atom is represent by $d^2 R / d t^2$, then

$$\begin{aligned} m_p \frac{d^2 R}{d t^2} & =F=\frac{1}{3} \frac{N Y^2 e^2 R}{\varepsilon_0}-\frac{4 \pi}{3} G m_P^2 N R \\ & =\left(\frac{1}{3} \frac{N Y^2 e^2}{\varepsilon_0}-\frac{4 \pi}{3} G m_p^2 N\right) R \\ \therefore\quad\frac{d^2 R}{d t^2} & =\frac{1}{m_p}\left[\frac{1}{3} \frac{N Y^2 e^2}{\varepsilon_0}-\frac{4 \pi}{3} G m_P^2 N\right] R \quad \text{... (iv)}\\ \text{where,}\quad\alpha^2 & =\frac{1}{m_p}\left[\frac{1}{3} \frac{N Y^2 e^2}{\varepsilon_0}-\frac{4 \pi}{3} G m_P^2 N\right] \end{aligned}$$

The general solution of Eq. (iv) is given by $R=A e^{\alpha t}+B e^{-\alpha t}$. We are looking for expansion, here, so $B=0$ and $R=A e^{\alpha t}$.

$\Rightarrow \quad$ Velocity of expansion, $v=\frac{d R}{d t}=A e^{\alpha t}(\alpha)=\alpha A e^{\alpha t}=\alpha R$

Hence, $v \propto$ R i.e., velocity of expansion is proportional to the distance from the centre.

(a) Let us consider a sphere $S$ of radius $R$ and two hypothetic sphere of radius $rR$.

Now, for point $r

$$\begin{aligned} & \oint E d S=\frac{1}{\varepsilon_0} \int \rho d V \\ & \text { [For } \left.d V, V=\frac{4}{3} \pi r^3 \Rightarrow d V=3 \times \frac{4}{3} \pi r^3 d r=4 \pi r^2 d r\right] \\ & \Rightarrow \quad \quad \quad \mathrm{E} . \mathrm{dS}=\frac{1}{\varepsilon_0} 4 \pi K \int_0^r r^3 d r \quad (\because p(r)=Kr)\\ & \Rightarrow \quad \text { (E) } 4 \pi r^2=\frac{4 \pi K}{\varepsilon_0} \frac{r^4}{4} \\ & \Rightarrow \quad E=\frac{1}{4 \varepsilon_0} K r^2 \end{aligned}$$

Here, charge density is positive.

So, direction of E is radially outwards.

For points $r>R$, electric field intensity will be given by

$$\begin{array}{rlrl} & & \rho E d S & =\frac{1}{\varepsilon_0} \int \rho \cdot d V \\ \Rightarrow \quad & E\left(4 \pi r^2\right) & =\frac{4 \pi K}{\varepsilon_0} \int_0^R r^3 d r=\frac{4 \pi K}{\varepsilon_0} \frac{R^4}{4} \\ \Rightarrow \quad & E & =\frac{K}{4 \varepsilon_0} \frac{R^4}{r^2} \end{array}$$

Charge density is again positive. So, the direction of E is radially outward.

(b) The two protons must be on the opposite sides of the centre along a diameter following the rule of symmetry. This can be shown by the figure given below. Charge on the sphere,

$$\begin{aligned} & q=\int_0^R \rho d V=\int_0^R(K r) 4 \pi r^2 d r \\ & q=4 \pi K \frac{R^4}{4}=2 e \\ \therefore\quad& K=\frac{2 e}{\pi R^4} \end{aligned}$$

If protons 1 and 2 are embedded at distance $r$ from the centre of the sphere as shown, then attractive force on proton 1 due to charge distribution is

$$F_1=e E=\frac{-e K r^2}{4 \varepsilon_0}$$

Repulsive force on proton 1 due to proton 2 is

$$\begin{aligned} F_2 & =\frac{e^2}{4 \pi \varepsilon_0(2 r)^2} \\ \text{Net force on proton 1,}\quad F & =F_1+F_2 \\ F & =\frac{-e K r^2}{4 \varepsilon_0}+\frac{e^2}{16 \pi \varepsilon_0 r^2} \\ \text{So,}\quad F & =\left[\frac{-e r^2}{4 \varepsilon_0} \frac{Z e}{\pi R^4}+\frac{e^2}{16 \pi \varepsilon_0 r^4}\right] \end{aligned}$$

Thus, net force on proton 1 will be zero, when

$$\begin{aligned} \frac{e r^2 2 e}{4 \varepsilon_0 \pi R^4} & =\frac{e^2}{16 \pi \varepsilon_0 r} \\ r^4 & =\frac{R^4}{8} \\ r & =\frac{R}{(8)^{1 / 4}} \end{aligned}$$

This is the distance of each of the two protons from the centre of the sphere.

(a) Net electric field at plate $\gamma$ before collision is equal to the sum of electric field at plate $\gamma$ due to plate $\alpha$ and $\beta$.

The electric field at plate $\gamma$ due to plate $\alpha$ is $E_1=\frac{-Q}{S\left(2 \varepsilon_0\right)}$, to the left.

The electric field at plate $\gamma$ due to plate $\beta$ is $E_2=\frac{q}{S\left(2 \varepsilon_0\right)}$, to the right.

Hence, the net electric field at plate $\gamma$ before collision.

$$E=E_1+E_2=\frac{q-Q}{S\left(2 \varepsilon_0\right)} \text {, to the left, if } Q>q$$

(b) During collision, plates $\beta$ and $\gamma$ are together. Their potentials become same.

Suppose charge on plate $\beta$ is $q_1$ and charge on plate $\gamma$ is $q_2$. At any point $O$, in between the two plates, the electric field must be zero.

Electric field at $O$ due to plate $\alpha=\frac{-Q}{S\left(2 \varepsilon_0\right)}$, to the left Electric field at $O$ due to plate $\beta=\frac{q_1}{S\left(2 \varepsilon_0\right)}$, to the right

Electric field at $O$ due to plate $\gamma=\frac{q_2}{S\left(2 \varepsilon_0\right)}$, to the left

As the electric field at $O$ is zero, therefore

$$\begin{aligned} \frac{Q+q_2}{S\left(2 \varepsilon_0\right)} & =\frac{q_1}{S\left(2 \varepsilon_0\right)} \\ \therefore\quad Q+q_2 & =q_1 \\ Q & =q_1-q_2\quad\text{... (i)} \end{aligned}$$

As there is no loss of charge on collision,

$$Q+q=q_1+q_2\quad\text{... (ii)}$$

$$\begin{aligned} &\text { On solving Eqs. (i) and (ii), we get }\\ &\begin{aligned} q_1 & =(Q+q / 2)=\text { charge on plate } \beta \\ q_2 & =(q / 2)=\text { charge on plate } \gamma \end{aligned} \end{aligned}$$

(c) After collision, at a distance $\alpha$ from plate $\beta$,

Let the velocity of plate $\gamma$ be $v$. After the collision, electric field at plate $\gamma$ is

$$E_2=\frac{-Q}{2 \varepsilon_0 S}+\frac{(Q+q / 2)}{2 \varepsilon_0 S}=\frac{q / 2}{2 \varepsilon_0 S} \text { to the right. }$$

Just before collision, electric field at plate $\gamma$ is $E_1=\frac{Q-q}{2 \varepsilon_0 S}$.

If $F_1$ is force on plate $\gamma$ before collision, then $F_1=E_1 Q=\frac{(Q-q) Q}{2 \varepsilon_0 S}$

Total work done by the electric field is round trip movement of plate $\gamma$

$$\begin{aligned} W & =\left(F_1+F_2\right) d \\ & =\frac{\left[(Q-q) Q+(q / 2)^2\right] d}{2 \varepsilon_0 S}=\frac{(Q-q / 2)^2 d}{2 \varepsilon_0 S} \end{aligned}$$

If $m$ is mass of plate $\gamma$, the KE gained by plate $\gamma=\frac{1}{2} m v^2$

According to work-energy principle, $\frac{1}{2} m v^2=W=\frac{(Q-q / 2)^2 d}{2 \varepsilon_0 S}$

$$\gamma=(Q-q / 2)\left(\frac{d}{m \varepsilon_0 S}\right)^{1 / 2}$$

(i) From the relation, $F=\frac{Q q}{r^2}=1$ dyne $=\frac{[1 \text { esu of charge }]^2}{[1 \mathrm{~cm}]^2}$

So, 1 esu of charge $=(1 \text { dyne })^{1 / 2} \times 1 \mathrm{~cm}=F^{1 / 2} \cdot \mathrm{~L}=\left[\mathrm{MLT}^{-2}\right]^{1 / 2} \mathrm{~L}$

$\Rightarrow 1$ esu of charge $=M^{1 / 2} L^{3 / 2} T^{-1}$.

Thus, esu of charge is represented in terms of fractional powers $\frac{1}{2}$ of $M$ and $\frac{3}{2}$ of $L$.

(ii) Let 1 esu of charge $=x C$, where $x$ is a dimensionless number. Coulomb force on two charges, each of magnitude 1 esu separated by 1 cm is dyne $=10^{-5} \mathrm{~N}$. This situation is equivalent to two charges of magnitude $x \mathrm{C}$ separated by $10^{-2} \mathrm{~m}$.

$\therefore \quad F=\frac{1}{4 \pi \varepsilon_0} \frac{x^2}{\left(10^{-2}\right)^2}=1$ dyne $=10^{-5} \mathrm{~N}$

$\therefore \quad \frac{1}{4 \pi \varepsilon_0}=\frac{10^{-9}}{x^2} \frac{\mathrm{Nm}^2}{\mathrm{C}^2}$

Taking, $\quad x=\frac{1}{|3| \times 10^9}$,

we get, $\quad \frac{1}{4 \pi \varepsilon_0}=10^{-9} \times|3|^2 \times 10^{18} \frac{\mathrm{Nm}^2}{\mathrm{C}^2}=9 \times 10^9 \frac{\mathrm{Nm}^2}{\mathrm{C}^2}$

If $|3| \rightarrow 2.99792458$, we get $\frac{1}{4 \pi \varepsilon_0}=8.98755 \times 10^9 \mathrm{Nm}^2 \mathrm{C}^{-2}$.