The de-Broglie wavelength L associated with an elementary particle of linear momentum p is best represented by the graph:

1. 

2. 

3. 

4. 

An electron of mass m, when accelerated through a potential difference, has de-Broglie wavelength $\lambda$ .The de-Broglie wavelength associated with a proton of mass M accelerated through the same potential difference will be:

1. $\lambda \frac{m}{M}$

2. $\lambda \sqrt{\frac{m}{M}}$

3. $\lambda \frac{M}{m}$

4. $\lambda \sqrt{\frac{M}{m}}$

An electron (mass m) with an initial velocity v=$v_0\hat{i}$ is in an electric E=$E_o\hat{j}$. If ${\lambda }_0=h/m{v}_0$, its de-Broglie wavelength at time t is given by

1. ${\lambda }_0$

2. ${\lambda }_0\sqrt{1+\frac{e^2{E}_0^2{t}^2}{m^2{v}_0^2}}$

3. $\frac{{\lambda }_0}{\sqrt{1+{\displaystyle \frac{e^2{E^2}_0{t}^2}{m^2{v^2}_0}}}}$

4. $\frac{{\lambda }_0}{\left(1+{\displaystyle \frac{e^2{E^2}_0{t}^2}{m^2{v^2}_0}}\right)}$

What should be the velocity of an electron so that its momentum becomes equal to that of a photon of wavelength 5200 $\stackrel{0}{A}$?

1. ${10}^3 m{s}^{-1}$

2. $1.2\times {10}^3 m{s}^{-1}$

3. $1.4\times {10}^3 m{s}^{-1}$

4. $2.8\times {10}^3 m{s}^{-1}$

An electron and photon have the same wavelength. If E is the energy of photon and  p is the momentum of the electron, then the magnitude of $\frac{E}{p}$ in SI unit is:

1. $3.33\times {10}^{-9}$

2. $3.0\times {10}^8$

3. $1.1\times {10}^{-19}$

4. $9\times {10}^{16}$

The difference between kinetic energies of photoelectrons emitted from a surface by light of wavelength 2500 $\stackrel{0}{A}$ and 500 $\stackrel{0}{A}$ will be

1. 1.61 J

2. 2.47 J

3. 3.96 J

4. $3.9\times {10}^{-19} J$

When a point source of light is 1 m away from a photoelectric cell, the photoelectric current is found to be I mA. If the same source is placed at 4 m from the same photoelectric cells, the photoelectric current (in mA) will be:

1. $\frac{I}{16}$

2. $\frac{I}{4}$

3. $4\mathrm{I}$

4. $16 \mathrm{I}$
 

The work function of tungsten and sodium is 4.5 eV and 2.3 eV respectively. If the threshold wavelength $\lambda$ for sodium is 5460 $\stackrel{0}{A}$, the value of $\lambda$ for tungsten is:
 

1. 2791 $\stackrel{0}{A}$

2. 3260 $\stackrel{0}{A}$

3. 1925 $\stackrel{0}{A}$

.4 1000 $\stackrel{0}{A}$

A photon of energy E ejects a photoelectrons from a metal surface whose work function is $W_0$. If this electron enters into a uniform magnetic field of induction B in a direction perpendicular to the field and describes a circular path of radius r, then the radius r is, given by:

1. $\sqrt{\frac{2m (W_0-E)}{eB}}$

2. $\sqrt{\frac{2e (E-W_0)}{mB}}$

3. $\sqrt{\frac{2m (E-W_0)}{eB}}$

4. $\sqrt{\frac{2m{W}_0}{eB}}$

A metal surface of work function 1.07 eV is irradiated with light of wavelength 332 nm. The retarding potential required to stop the escape of photoelectrons is:

1. 1.07 V

2. 2.66 V

3. 3.7 V

4. 4.81 V