In a location in outer space far from all other objects, a nucleus whose mass is 3.89104e-25 kg and which is initially at rest undergoes spontaneous \"alpha" decay. The original nucleus disappears, and two new particles appear: a He4 nucleus of mass 6.640678e27 kg (an "alpha particle" consisting of two protons and two neutrons) and a new nucleus of mass 3.824534e-25 kg. These new particles move far away from each other, because they repel each other electrically (both are positively charged). Because the calculations involve the small difference of (comparatively) large numbers, you need to keep 7 signicant gures in your calculations, and you need to use the more accurate value for the speed of light, 2.99792e8 m/s. Choose all particles as the system. Initial state: Original nucleus, at rest. Final state: Alpha particle + new nucleus, far from each other. What is the rest energy of the original nucleus? Gr've 7signr'cant gures. rest energy = [:l J What is the sum of the rest energies of the alpha particle and the new nucleus? Give 7sr'gnr'fr'cant gures. sum of rest energies = :l J The portion of the total energy of the system contributed by rest energy: Therefore the portion of the total energy of the system contributed by kinetic energy: What is the sum of the kinetic energies of the alpha particle and the new nucleus? Kalpha + lKnew nucleus = :'J Additional Materials D eBook