Question:
Surface of certain metal is first illuminated with light of wavelength $\lambda_1 =350 \; nm$ and then, by light of wavelength $\lambda_2=54\, \; nm$. It is found that the maximum speed of the photo electrons in the two cases differ by a factor of $2$. The work function of the metal (in eV) is close to :
(Energjr of photon = $\frac{1240}{\lambda (in \; nm)} eV$)
Surface of certain metal is first illuminated with light of wavelength $\lambda_1 =350 \; nm$ and then, by light of wavelength $\lambda_2=54\, \; nm$. It is found that the maximum speed of the photo electrons in the two cases differ by a factor of $2$. The work function of the metal (in eV) is close to :
(Energjr of photon = $\frac{1240}{\lambda (in \; nm)} eV$)
Updated On: Apr 1, 2026
- 1.8
- 1.4
- 2.5
- 5.6
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The Correct Option is A
Solution and Explanation
$\frac{hc}{\lambda_{1}} =\phi + \frac{1}{2} m\left(2v\right)^{2} $
$\frac{hc}{\lambda _{2}} =\phi + \frac{1}{2} mv^{2} $
$\Rightarrow \frac{\frac{hc}{\lambda _{1}}-\phi}{\frac{hc}{\lambda _{2}} -\phi} = 4 $
$\Rightarrow \frac{hc}{\lambda _{1}} - \phi = \frac{4hc}{\lambda _{2}} -4 \phi $
$ \Rightarrow \frac{4hc}{\lambda _{2}} - \frac{hc}{\lambda _{1}} = 3\phi $
$ \Rightarrow \phi = \frac{1}{3} hc \left(\frac{4}{\lambda _{2}} -\frac{1}{\lambda _{1}}\right) $
$= \frac{1}{3} \times1240 \left(\frac{4 \times350 -540}{350\times540} \right) $
$= 1.8 \,eV $
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Concepts Used:
Photoelectric Effect
When light shines on a metal, electrons can be ejected from the surface of the metal in a phenomenon known as the photoelectric effect. This process is also often referred to as photoemission, and the electrons that are ejected from the metal are called photoelectrons.
Photoelectric Effect Formula:
According to Einstein’s explanation of the photoelectric effect :
The energy of photon = energy needed to remove an electron + kinetic energy of the emitted electron
i.e. hν = W + E
Where,
- h is Planck’s constant.
- ν is the frequency of the incident photon.
- W is a work function.
- E is the maximum kinetic energy of ejected electrons: 1/2 mv².
Laws of Photoelectric Effect:
- The photoelectric current is in direct proportion to the intensity of light, for a light of any given frequency; (γ > γ Th).
- There exists a certain minimum (energy) frequency for a given material, called threshold frequency, below which the discharge of photoelectrons stops completely, irrespective of how high the intensity of incident light is.
- The maximum kinetic energy of the photoelectrons increases with the increase in the frequency (provided frequency γ > γ Th exceeds the threshold limit) of the incident light. The maximum kinetic energy is free from the intensity of light.
- The process of photo-emission is an instantaneous process.