Emergence of Wigner oscillations in a model of real time cooling process: a time-dependent density-functional theory approach

Friedel and Wigner oscillations are well known phenomena occurring in quantum systems. Specifically, in a system composed by N confined particles, the former are characterized by the presence of N/2 peaks in the density distributions, whereas the last by N peaks. Here, we consider N=2 electrons harmonically confined in one-dimensional quantum dots. It is known that the transition from the Friedel to the Wigner oscillations is induced by the increment of interaction between the electrons. The increment of temperature, on the other hand, acts on eliminating the oscillations. In this context, by employing a time-dependent density-functional theory formalism, we obtain the emergence of Wigner oscillations in a model which simulates a real time cooling process.