Strong energy relaxation of propagating quasiparticles in the quantum Hall regime

R. H. Rodriguez, F. D. Parmentier, P. Roulleau, U. Gennser, A. Cavanna, F. Portier, D. Mailly, P. Roche

Published 2019-03-14Version 1

The current-carrying edge channels of the quantum Hall effect are a widely used toolbox to perform a rich variety of quantum electronics experiments in which one seeks, inspired by quantum optics, to coherently manipulate the trajectories of single electronic wave packets. This so-called field of electron quantum optics has recently shown significant progress towards fully quantum coherent electronics using propagating single quasiparticles. However, contrary to photons, electrons are Fermionic particles strongly interacting with their environment because of long-range Coulomb interactions. For excitations close to the Fermi energy, this interaction has been shown to cause decoherence and energy relaxation over micron length scales. Here we show that quasiparticles injected at a well-defined energy in an edge channel - a paradigm of electron quantum optics - undergo unexpectedly a much stronger energy relaxation. On sub-micron lengths, quasiparticles gush into the Fermi sea with a survival probability decreasing exponentially with their energy. Unmitigated, this relaxation is clearly detrimental to any quantum applications.