Advertisements
Advertisements
Question
An electron and a positron moving at small speeds collide and annihilate each other. Find the energy of the resulting gamma photon.
Solution
We know,
Mass of electron = Mass of positron = 9.1 × 10−31 kg
Both are oppositely charged and annihilate each other to form a gamma photon of rest mass zero. Thus,
∆m = me + mp = 2 × 9.1 × 10−31 kg
This mass will be converted into energy of the resulting γ photon. Thus,
Eγ= ∆mc2
Eγ = 2 × 9.1 × 10−31 × 9 × 1016 J
\[= \frac{2 \times 9 . 1 \times 9 \times {10}^{- 15}}{1 . 6 \times {10}^{- 19}}\]
\[ = 102 . 37 \times {10}^4 eV\]
\[ = 1 . 02 \times {10}^5 eV\]
\[ = 1 . 02 MeV\]
APPEARS IN
RELATED QUESTIONS
Mass of a particle depends on its speed. Does the attraction of the earth on the particle also depend on the particle's speed?
If the speed of a particle moving at a relativistic speed is doubled, its linear momentum will _____________ .
Mark the correct statements:-
(a) Equations of special relativity are not applicable for small speeds.
(b) Equations of special relativity are applicable for all speeds.
(c) Nonrelativistic equations give exact result for small speeds.
(d) Nonrelativistic equations never give exact result.
If the speed of a rod moving at a relativistic speed parallel to its length is doubled,
(a) the length will become half of the original value
(b) the mass will become double of the original value
(c) the length will decrease
(d) the mass will increase
Which of the following quantities related to an electron has a finite upper limit?
When a rod moves at a relativistic speed v, its mass ________________ .
By what fraction does the mass of a spring change when it is compressed by 1 cm? The mass of the spring is 200 g at its natural length and the spring constant is 500 N m−1.
Find the increase in mass when 1 kg of water is heated from 0°C to 100°C. Specific heat capacity of water = 4200 J kg−1 K−1.
A 100 W bulb together with its power supply is suspended from a sensitive balance. Find the change in the mass recorded after the bulb remains on for 1 year.
The energy from the sun reaches just outside the earth's atmosphere at a rate of 1400 W m−2. The distance between the sun and the earth is 1.5 × 1011 m.
(a) Calculate the rate which the sun is losing its mass.
(b) How long will the sun last assuming a constant decay at this rate? The present mass of the sun is 2 × 1030 kg.
Through what potential difference should an electron be accelerated to give it a speed of (a) 0.6c, (b) 0.9c and (c) 0.99c?
Find the speed of an electron with kinetic energy (a) 1 eV, (b) 10 keV and (c) 10 MeV.
What is the kinetic energy of an electron in electron volts with mass equal to double its rest mass?
