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Question: An \[\alpha \] particle has an initial kinetic energy of 25eV and it is accelerated through the pote...

An α\alpha particle has an initial kinetic energy of 25eV and it is accelerated through the potential difference of 150 volt. If a proton has initial kinetic energy of 25eV and it is accelerated through the potential difference of 25 volt then find the approximate ratio of the final wavelengths associated with the proton and the α\alpha particle.
a.) 5:1
b.) 13:5
c.) 26:1
d.) 26:5

Explanation

Solution

Hint: To solve this question, we must focus on the wave nature of particle. We should recall the relationship between deBroglie wavelength and kinetic energy of particles.

Complete step by step answer:
We know that Louis deBroglie (Nobel Prize in Physics in 1929) had proposed that a wave function is associated with all particles. Wherever this wave function has non-zero amplitude, we may find the particle in all probability. This means that the intensity of the wave function of a particle at any point is proportional to the probability of finding the particle at that point.
The mathematical relation between kinetic energy of the particle and its deBroglie wavelength can be obtained from the following equation:
λ=hp\lambda = \dfrac{h}{p}
Where, h is Planck's constant and p is the momentum of the particle.
On substituting momentum with kinetic energy, the equation takes the form:
λ=h2mKE\lambda = \dfrac{h}{{\sqrt {2m\,KE} }}
Since,
Now we calculate the total kinetic energy.
For alpha particle: 25 + 2(150) = 325eV
For proton: 25 + 1(25) = 50eV
The ratio of wavelength therefore:
λαλp=mp×Energypmα×Energyα\dfrac{{{\lambda _\alpha }}}{{{\lambda _p}}} = \dfrac{{{m_p} \times Energ{y_p}}}{{{m_\alpha } \times Energ{y_\alpha }}}
= λαλp=1×504×325=126\dfrac{{{\lambda _\alpha }}}{{{\lambda _p}}} = \dfrac{{1 \times 50}}{{4 \times 325}} = \dfrac{1}{{26}}
Hence, the correct answer is Option (C) 26:1

Additional Information:
Although it was proved theoretically before, the first experimental verification of de Broglie's hypothesis came from two physicists working at Bell Laboratories in the USA in 1926. They scattered electrons off Nickel crystals and noticed that the electrons were more likely to appear at certain angles than others. This was the Davisson-Germer experiment.

Note: We must keep in mind the limitation of deBroglie’s principle. deBroglie's wavelength is only valid for quantum particles. Although waves are formed for macroscopic particles as well, their wavelength is negligibly small.