By virtue of their enormous variability, single-molecule devices offer a fascinating arena for realizing novel effects in quantum transport through nanostructures. A natural source for such effects lies in the coupling of the electronic degrees of freedom to few, well-defined molecular vibrations. This coupling is specific to molecules as opposed to conventional nanostructures such as quantum dots, where one commonly deals with a continuum of phonon modes. One expects new regimes of quantum transport for at least two reasons: (i) The transport current can excite nonequilibrium molecular vibrations. We predicted that this can lead to current flow in the form of a self-similar hierarchy of avalanches of many electrons. (ii) Polaron shifts of the molecular levels can renormalize the charging energy to negative values, analogous to negative-U centers in amorphous semiconductors. Very recently, we showed that transport through such negative-U molecules is dominated by tunneling of electron pairs.We propose to study these interesting modes of transport through molecular junctions by pursuing a two-pronged research program. First, we will push to understand transport in these situations beyond the rate-equation regime, which is expected to uncover additional physics. Second, we will go beyond the minimal model of molecular junctions employed in previous studies in an effort to achieve a more realistic and complete description of possible experimental systems. Finally, we will also search for further novel modes of quantum transport in molecular junctions.

DFG Programme Priority Programmes

Subproject of SPP 1243:  Quantum Transport at the Molecular Scale