Question:

The velocities of two particles $A$ and $B$ are $0.05$ and $0.02\, ms^{-1}$ respectively. The mass of $B$ is five times the mass of $A$. The ratio of their de- Broglie's wavelength is

Updated On: Jun 18, 2022
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The Correct Option is A

Solution and Explanation

Given, velocity of particle $A=0.05\, ms ^{-1}$
Velocity of particle $B=0.02\, ms ^{-1}$
Let the mass of particle $A=x$
$\therefore$ The mass of particle $B=5 x$
de-Broglie's equation is
$\lambda=\frac{h}{m v}$
For particle $A$
$\lambda_{A}=\frac{h}{x \times 0.05} ...(i)$
For particle B
$\lambda=\frac{h}{5 x \times 0.02}...(ii)$
Eq (i)/(ii)
$\frac{\lambda_{A}}{\lambda_{B}}=\frac{5 x \times 0.02}{x \times 0.05}$
$\frac{\lambda_{A}}{\lambda_{B}}=\frac{2}{1}$
Or $2: 1$
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Concepts Used:

Quantum Mechanical Model of the Atom

Quantum Mechanics:

Quantum mechanics is an evolving and much-advanced field of science that aims at understanding the properties of matter and objects in relation to their corresponding atomic and sub-atomic nature. It further illustrates the characteristics of the atoms, protons, electrons, and neutrons specifically and in the context of each other. It aims at studying electromagnetic radiation as well. This is a sub-part of the wider theory of quantum physics.

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Quantum Mechanical Models:

Presently, the scientific world has only two acceptable and working models of quantum mechanics. Such as,

  • The first model for the understanding and application of quantum mechanics that is acceptable currently is the Bohr Model.

The basis of this model of the Bohr is seen in terms of mathematics which is used for understanding the complex structures.

  • Another acceptable model is the Quantum Mechanics Model which has its basis in quantum theory.

This quantum theory ultimately defines the exact properties of matter over a period of time. It usually works on the uncertainty principle.