Time dilation in the oscillating decay laws of moving two-mass unstable quantum states

Abstract

The decay of a moving system is studied in case the system is initially prepared in a two-mass unstable quantum state. The survival probability Pp(t) is evaluated over short and long times in the reference frame where the unstable system moves with constant linear momentum p. The mass distribution densities of the two mass states are tailored as power laws with powers α1 and α2 near the non-vanishing lower bounds μ0,1 and μ0,2 of the mass spectra, respectively. If the powers α1 and α2 differ, the long-time survival probability Pp(t) exhibits a dominant inverse-power-law decay and is approximately related to the survival probability at rest P0(t) by a time dilation. The corresponding scaling factor p,k reads 1+p2/μ0,k2, the power αk being the lower of the powers α1 and α2. If the two powers coincide and the lower bounds μ0,1 and μ0,2 differ, the scaling relation is lost and damped oscillations of the survival probability Pp(t) appear over long times. By changing reference frame, the period T0 of the oscillations at rest transforms in the longer period Tp according to a factor which is the weighted mean of the scaling factors of each mass, with non-normalized weights μ0,1 and μ0,2.