COMEDK 2024 Shift 2 Paper

To find the velocity of the particle of mass 2 mg that has the same wavelength as a neutron moving with a velocity of 3×105ms−1, we can use the de Broglie wavelength formula:
λ=‌

h

mv

Where:
λ is the wavelength
h is Planck's constant (approximately 6.626×10−34‌Js )
m is the mass of the particle
v is the velocity of the particle
First, let's find the wavelength of the neutron. The mass of the neutron is given as 1.67×10−27‌Kg and its velocity is 3×105ms−1.

Plugging in the values:
λ=‌

6.626×10−34

1.67×10−27⋅3×105

Let's calculate this:
‌λ=‌

6.626×10−34

5.01×10−22

‌λ≈1.322×10−12m
Since the particle of mass 2 mg has the same wavelength, we can use this value to find its velocity. The mass of the particle is:
m‌particle ‌=2‌mg=2×10−3g=2×10−6‌Kg
Now, using the de Broglie formula again:
v‌particle ‌=‌

h

λ⋅m‌particle ‌

Plugging in the values:

v‌particle ‌=‌

6.626×10−34

1.322×10−12⋅2×10−6

Let's calculate this:
‌v‌particle ‌=‌

6.626×10−34

2.644×10−18

‌v‌particle ‌≈2.507×10−16ms−1
v‌particle ‌=‌

6.626×10−34

1.322×10−12⋅2×10−6

Let's calculate this:
‌v‌particle ‌=‌

6.626×10−34

2.644×10−18

‌v‌particle ‌≈2.507×10−16ms−1
Thus, the velocity of the particle is approximately 2.5×10−16ms−1, which corresponds to option A.
Option A: 2.5×10−16ms−1