Alpha Particle
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The following quantities appear in the problem:
Masse \(m\) / Energie \(E\) / Geschwindigkeit \(v\) / Lorentz-Faktor \(\gamma\) /
The following formulas must be used to solve the exercise:
\(E_k = (\gamma-1)mc^2 \quad \) \(\gamma = \frac{1}{\sqrt{1-\frac{v^2}{c^2}}} \quad \)
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Exercise:
Calculate the velocity of an alpha particle with a kinetic energy of EkO.
Solution:
The Lorentz factor is gamma +fracsscEkinE_ fracE_ + sscEkinE_ It follows for the velocity beta sqrt-fracgamma^ beF sqrt-fracEr^Er+Ek^ resultbeP The classical calculation yields a value of v_textrmcl sqrtfrac sscEkinm vcF sqrtfrac times EkErtimes c vcP In this example the classical calculation is only slighty higher than the relativistic one. For higher velocities the deviations become much more significant.
Calculate the velocity of an alpha particle with a kinetic energy of EkO.
Solution:
The Lorentz factor is gamma +fracsscEkinE_ fracE_ + sscEkinE_ It follows for the velocity beta sqrt-fracgamma^ beF sqrt-fracEr^Er+Ek^ resultbeP The classical calculation yields a value of v_textrmcl sqrtfrac sscEkinm vcF sqrtfrac times EkErtimes c vcP In this example the classical calculation is only slighty higher than the relativistic one. For higher velocities the deviations become much more significant.