Tag: concept of photon

Questions Related to concept of photon

Multiple choice physics quantum physics photons concept of photon photons and photoelectric effect

The energy of the incident photon is 12.38 eV, while the energy of the scattered photon is 9.4 eV. The K.E. of the recoil electron is nearly

  1. 2 eV

  2. 1 eV

  3. 4 eV

  4. 3 eV

Reveal answer Fill a bubble to check yourself
D Correct answer
Explanation

K.E of the recoil electron
= energy of the incident photon - energy of scattered photon
= 12.38 eV -9.4eV
$\simeq 3eV.$

So, the answer is option (D).

Multiple choice physics quantum physics photons concept of photon photons and photoelectric effect

Light of wavelength 5000 $A^{o}$ falls on a sensitive plate with photoelectric work function 1.9eV. The maximum kinetic energy of the photoelectrons emitted will be

  1. $0.58 \ eV$

  2. $2.48 \ eV$

  3. $1.24 \ eV$

  4. $1.16 \ eV$

Reveal answer Fill a bubble to check yourself
A Correct answer
Explanation

$\lambda =5000 A^{0}  =  500nm$

$K.E. _{max} =\dfrac{hc}{\lambda }-\phi $

$=\dfrac{1240}{500}-1.9 \ \ \ \  (hc = 1240  eV - nm)$

$=2.48-1.9$
$=0.58 \ eV$
So, the answer is option (A).

Multiple choice physics quantum physics photons concept of photon photons and photoelectric effect

When light of wavelength 2480 $A^{0}$ is incident on a metal surface electrons are emitted with a maximum KE of 2 eV. The maximum KE of photo-electrons, if light of wavelength 1240 $A^{0}$ is incident on the same surface would be

  1. 4eV

  2. 1 eV

  3. 2eV

  4. 7eV

Reveal answer Fill a bubble to check yourself
D Correct answer
Explanation

From the 1st condition
$\dfrac{hC}{\lambda} - W = 2eV$

$h \ in \ terms \ of \ eV = \dfrac{6.63 \times 10^{-34}}{1.6 \times 10^{-19}}$

$\Rightarrow \dfrac{4.14 \times 10^{-15} \times 3 \times 10^{8} \times 10^{10}}{2480}$

$\Rightarrow Work for = \left ( 5.012 - 2 \right )eV$

$\Rightarrow W \approx 3eV$

So,
In 2nd case when wavelength of incident light is $1240 A^{\circ}$,
$\Rightarrow \dfrac{hC}{\lambda} - W = K. E.$

$\Rightarrow K. E. = \dfrac{4.14 \times 10^{-15} \times 3 \times 10^{18}}{1240} - 3$

$=10 - 3 = 7eV$

So, the answer is option (D).

Multiple choice physics quantum physics photons concept of photon photons and photoelectric effect

The cut-off voltage in a photoelectric experiment is 3V. Then the maximum KE of photo-electrons emitted is

  1. 3 V

  2. 3 eV

  3. 6 eV

  4. 9 eV

Reveal answer Fill a bubble to check yourself
B Correct answer
Explanation

Cut off voltage is the minimum voltage applied across the plates that even the electrons ejected with minimum kinetic energy could not reach the other plate.
So, 
From the definition,
Cut off voltage $= 3V$
Work done on the charge $=$ Kinetic energy of the photons
$\Rightarrow 3V \times 1e = K. E.$
$\Rightarrow K. E. = 3eV$

So, the answer is option (B).

Multiple choice physics quantum physics photons concept of photon photons and photoelectric effect

If the frequency of light incident on a photosensitive metal plate is doubled, then the KE of photoelectrons will be

  1. Doubled

  2. Halved

  3. Quadrupled

  4. More than twice the previous value

Reveal answer Fill a bubble to check yourself
D Correct answer
Explanation

$\ KE\ =\ h(V-V _{0})$
$\ V^{1}\ =\ 2V$
$\ KE^{1}\ =\ h(2V-V _{0})$
$\ KE^{1}\ =\ 2h(V-V _{0}) +\ hV _{0}$
$\ KE^{1}\ =\ 2KE+hV _{0}$

So, the answer is option (D).

Multiple choice physics quantum physics photons concept of photon photons and photoelectric effect

The photo-electric threshold wavelength for a metal is $5000 A^{0}$. Light of wavelength $4000 A^{0}$ is incident on it. The maximum KE of photo-electrons emitted is [given $hc= 2 \times 10^{-25} Jm$]

  1. $3.1 eV$

  2. $2.48 eV$

  3. $0.62 eV$

  4. $5. 58 eV$

Reveal answer Fill a bubble to check yourself
C Correct answer
Explanation

$K _{max}\ =\ \dfrac{hc}{\lambda}-\dfrac{hc}{\lambda _{0}}$

            $=\dfrac{20\times 10^{-26}}{4\times 10^{-7}}-\dfrac{20\times 10^{-26}}{5\times 10^{-7}}$

           $=\ 20\times 10^{-19}\left ( \dfrac{1}{4} -\dfrac{1}{5}\right )\ J$

          $=10^{-19}J=\dfrac{10^{-19}}{1.6\times 10^{-19}}eV=0.62eV$

So, the answer is option (C).

Multiple choice physics quantum physics photons concept of photon photons and photoelectric effect

An X-ray tube produces a continuous spectrum of radiation with its short wavelength end at 0.40$A^{0}$. Then the maximum energy of the photon of the emitted radiation. 

($h = 6.63 \times10^{-34}Js$ and $c= 3 \times10^{8}$ m/s)

  1. $4.9725\times 10^{-15}J$

  2. $6.28\times 10^{-15}J$

  3. $3.15\times 10^{-15}J$

  4. $2.98\times 10^{-15}J$

Reveal answer Fill a bubble to check yourself
A Correct answer
Explanation

$\lambda _{cutoff} =\ \dfrac{hc}{E}$

$E _{max}=\ \dfrac{20\times 10^{-26}}{0.4\times 10^{-10}}$

$=\ 4.9725\times 10^{-15}\ J$

So, the answer is option (A).

Multiple choice physics quantum physics photons concept of photon photons and photoelectric effect

The work function of a certian metal is 2.3 eV .If light of wave number $2\times10^{6}m^{-1}$ falls on it,the kinetic energies of fastest and slowest ejected electorn will be respectively:

  1. 2.48eV ,0.18eV

  2. 0.18eV,Zero

  3. 2.30eV,Zero

  4. 0.18eV,0.18eV

Reveal answer Fill a bubble to check yourself
B Correct answer
Explanation

$\phi _{ _0}=2.3eV$ 


$\lambda^{-1}=2\times10^6m^{-1}$


Some electrons, although get loosened due to the incident rays, remain stationary.
$\therefore KE _{min}=0$ always

$KE _{max}=TE-\phi _{ _0}$  where TE is the energy of the rays.

$TE=hc\lambda^{-1}$  in Joules

$TE=\dfrac{hc\lambda^{-1}}e$ $in$ $eV$ where e is the charge of one electron

$\therefore TE=\dfrac{6.63\times10^{-34}\times{3\times10^8}\times2\times 10^6}{1.6\times10^{-19}}=2.48eV$

$\therefore KE _{max}=2.48-2.3=0.18eV$

Multiple choice physics quantum physics photons concept of photon photons and photoelectric effect

The ratio of momentum  of an electron and an $\alpha$-particle which are accelerated from rest by a potential difference of 100 V is

  1. 1

  2. $\displaystyle \sqrt{\frac{2m _e}{m _\alpha}}$

  3. $\displaystyle \sqrt{\frac{m _e}{m _\alpha}}$

  4. $\displaystyle \sqrt{\frac{m _e}{2m _\alpha}}$

Reveal answer Fill a bubble to check yourself
C Correct answer
Explanation

Since both particles are accelerated by same potential difference, their kinetic energies are equal.

Thus $\dfrac{1}{2}m _{e}v _e^2=\dfrac{1}{2}m _{\alpha}v _{\alpha}^2$
$\implies \dfrac{v _e}{v _{\alpha}}=\sqrt{\dfrac{m _{\alpha}}{m _e}}$
Thus the ratio of their momenta=$\dfrac{m _ev _e}{m _{\alpha}v _{\alpha}}=\sqrt{\dfrac{m _e}{m _{\alpha}}}$
Hence correct answer is option C.

Multiple choice physics quantum physics photons concept of photon photons and photoelectric effect

Which one of the following branch of physics deals the impossibility of making simultaneous, arbitrarily precise measurements of the momentum and the position of an electron.

  1. thermodynamics

  2. quantum mechanics

  3. classical electrodynamics

  4. special relativity

  5. general relativity

Reveal answer Fill a bubble to check yourself
B Correct answer
Explanation

Heisenberg's Uncertainty Principle, as a part of quantum mechanics, theorizes that the position and momentum of an electron cannot be measured precisely at the same time, that is, there is a minimum associated natural error in measurement of the two simultaneously. 

The error in measurement of the two is quantified as $\Delta x.\Delta p\geq\dfrac{\hbar}{2}$