Reentrant localization in fractionally charged electron wave packets
Abstract
We investigate the localization transition in fractionally charged electron wave packets, which is injected into a quantum conductor by a single voltage pulse with arbitrary flux quantum. We show that the transition is unidirectional for individual electrons or holes. They always undergo a delocalization-to-localization transition as the flux increases. In contrast, the transition of the neutral electron-hole pairs is bidirectional. As the flux increases, the transition can be a localization-to-delocalization transition or vice versa, which is controlled via the long-time tail of the voltage pulse. The localization-to-delocalization transition occurs in the case of short-tailed pulses, which decay faster than Lorentzian. In this case, the directions of the transitions for the neutral eh pairs and individual electrons or holes are opposite. Certain localized neutral electron-hole pairs can first evolve into delocalized ones, then split into individual electrons and holes with localized wave functions, which gives a reentrant localization. The delocalization-to-localization transition occurs in the case of long-tailed pulses, which decay slower than Lorentzian. The reentrant localization vanishes in this case, as the directions of the two transitions are the same. It is also absent in the case of Lorentzian pulses, where the localized neutral electron-hole pairs cannot be excited at all.