Suppose wavelength of $X$-rays is $\lambda_1$ and the wavelength of visible light is $\lambda_2$.

$$\begin{aligned} \text{Given,}\quad P & =100 \mathrm{~W} \\ \lambda_1 & =1 \mathrm{~nm} \\ \text{and}\quad\lambda_2 & =500 \mathrm{~nm} \end{aligned}$$

Also, $n_1$ and $n_2$ represents number of photons of $X$-rays and visible light emitted from the two sources per sec.

So,

$$\begin{aligned} & \frac{E}{t}=P=n_1 \frac{h c}{\lambda_1}=n_2 \frac{h c}{\lambda_2} \\ \Rightarrow \quad & \frac{n_1}{\lambda_1}=\frac{n_2}{\lambda_2}\\ \Rightarrow \quad &\frac{n_1}{n_2}=\frac{\lambda_1}{\lambda_2}=\frac{1}{500} \end{aligned}$$

During photoelectric emission, the momentum of incident photon is transferred to the metal. At microscopic level, atoms of a metal absorb the photon and its momentum is transferred mainly to the nucleus and electrons.

The excited electron is emitted. Therefore, the conservation of momentum is to be considered as the momentum of incident photon transferred to the nucleus and electrons.

Given,

For the first condition, Wavelength of light $\lambda=600 \mathrm{~nm}$ and for the second condition, Wavelength of light $\lambda^{\prime}=400 \mathrm{~nm}$

Also, maximum kinetic energy for the second condition is equal to the twice of the kinetic energy in first condition.

i.e., $$K_{\max }^{\prime}=2 K_{\max }$$

$$\begin{aligned} & \begin{aligned} \text { Here, } \quad K_{\max }^{\prime} & =\frac{h c}{\lambda}-\phi \\ \Rightarrow \quad 2 K_{\max } =\frac{h c}{\lambda^{\prime}}-\phi_0 \\ \Rightarrow \quad 2\left(\frac{1230}{600}-\phi\right) & =\left(\frac{1230}{400}-\phi\right) \quad[\because h c \approx 1240 \mathrm{eVnm}] \\ \Rightarrow \quad \phi =\frac{1230}{1200}=1.02 \mathrm{eV} \end{aligned} \end{aligned}$$

Here, $\Delta x=1 \mathrm{~nm}=10^{-9} \mathrm{~m}, \Delta p=$ ?

As $\Delta x \Delta p \approx h$

$$\therefore\quad\Delta p=\frac{h}{\Delta x}=\frac{h}{2 \pi \Delta x}$$

$$\begin{aligned} \Rightarrow \quad & =\frac{6.62 \times 10^{-34} \mathrm{Js}}{2 \times(22 / 7)\left(10^{-9}\right) \mathrm{m}} \\ & =1.05 \times 10^{-25} \mathrm{~kg} \mathrm{~m} / \mathrm{s} \end{aligned}$$

$$\begin{aligned} &\text { Energy, }\quad E=\frac{p^2}{2 m}=\frac{(\Delta p)^2}{2 m} \quad[\because p \approx \Delta p] \end{aligned}$$

$$ \begin{aligned} & =\frac{\left(1.05 \times 10^{-25}\right)^2}{2 \times 9.1 \times 10^{-31}} \mathrm{~J} \\ \Rightarrow\quad & =\frac{\left(1.05 \times 10^{-25}\right)^2}{2 \times 9.1 \times 10^{-31} \times 1.6 \times 10^{-19}} \mathrm{eV} \\ & =3.8 \times 10^{-2} \mathrm{eV} \end{aligned}$$

Suppose $n_A$ is the number of photons falling per second of beam $A$ and $n_B$ is the number of photons falling per second of beam $B$.

$$\begin{aligned} \text{Thus,}\quad n_A & =2 n_B \\ \text{Energy of falling photon of beam}\quad A & =h v_A \\ \text{Energy of falling photon of beam }\quad B & =h v_B \end{aligned}$$

Now, according to question,

$$\begin{aligned} &\text { intensity of } A=\text { intensity of } B\\ &\begin{aligned} & \therefore \quad n_A h \nu_A=n_B h \nu_B \\ \Rightarrow\quad & \frac{\nu_A}{\nu_B}=\frac{n_B}{n_A}=\frac{n_B}{2 n_B}=\frac{1}{2} \\ \Rightarrow\quad & \nu_B=2 \nu_A \end{aligned} \end{aligned}$$

Thus, from this relation we can infer that frequency of beam B is twice of beam A.