Calculate the speed of the positron as measured in the frame of reference of the electron.

Calculate the total energy in the reaction.

Outline why two photons must be released in this collision.

Determine the frequency of one of the photons.

\({u'_x} = \frac{{{u_x} - v}}{{1 - \frac{{{u_x}v}}{{{c^2}}}}} = \frac{{0.85{\text{c}} - [ - 0.85{\text{c]}}}}{{1 + {{[0.85]}^2}}}\);

0.99c;

\(E = \left( {2[\gamma {m_0}{c^2}] = 2 \times 1.9 \times 0.511 = } \right){\text{ }}1.94{\text{ MeV}}\)\(\,\,\,\)or\(\,\,\,\)\(3.1 \times {10^{ - 13}}{\text{ J}}\);

total momentum before the collision is zero;

if only one photon is emitted then the total momentum after the collision cannot be zero, otherwise momentum will not be conserved;

\(f = \frac{E}{h} = \frac{{0.5 \times 1.9418 \times {{10}^6} \times 1.6 \times {{10}^{ - 19}}}}{{6.63 \times {{10}^{ - 34}}}}\) ; (allow ECF from (b)(i))

\(f = 2.3 \times {10^{20}}{\text{ Hz }}\);

Well prepared candidates showed a good ability to apply relativistic velocity addition. (b) discriminated well.

Well prepared candidates showed a good ability to apply relativistic velocity addition. (b) discriminated well.

Well prepared candidates showed a good ability to apply relativistic velocity addition. (b) discriminated well.

Well prepared candidates showed a good ability to apply relativistic velocity addition. (b) discriminated well.