This project must be done by individuals.

An isolated neutron is not stable. It decays into three particles:

- a proton
- an electron
- an anti-neutrino

Fill in the table below:

particle mass (kg) mass (MeV/c^2) --------------------------------------------------- neutron proton electron anti-neutrino ---------------------------------------------------

- What is the difference in mass between the initial neutron and the final products?
- How much energy does this correspond to?
Assume that the neutron is initially motionless. Suppose that after the decay, the proton is likewise motionless. The anti-neutrino, of course, can't be motionless, so it flies off at the speed of light to the right, in the positive x-direction.

- Draw a pair of pictures showing the "Before" and "After" arrangement of the particles, and their motions.
- Write an equation for the total energy of the particles in the "After" set.
- Write an equation for the total momentum of the particles in the "After" set.
- How fast must the electron fly away from the proton? Express your answer as a fraction of the speed of light.

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(Hint: the algebra in this problem isn't trivial. Feel free to
solve for the electron's speed numerically, as long as you
describe your method.)
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Copyright © Michael Richmond. This work is licensed under a Creative Commons License.