Dissipationless transport of electrons and Cooper pairs in an electron waveguide

Anil Annadi, Shicheng Lu, Hyungwoo Lee, Jung-Woo Lee, Guanglei Cheng, Anthony Tylan-Tyler, Megan Briggeman, Michelle Tomczyk, Mengchen Huang, David Pekker, Chang-Beom Eom, Patrick Irvin, Jeremy Levy

Published 2016-11-16Version 1

Electrons undergo profound changes in their behavior when constrained to move along a single axis. Theories of one-dimensional (1D) transport of interacting electron systems depend crucially on the sign of the electron-electron interaction. To date, clean 1D electron transport has only been reported in systems with repulsive interactions; SrTiO3-based heterointerfaces exhibit superconducting behavior with attractive interactions that are manifested far outside the superconducting regime. However, the relatively low mobilities of two-dimensional (2D) complex-oxide interfaces appear to preclude ballistic transport in 1D. Here we show that nearly ideal 1D electron waveguides exhibiting ballistic transport of electrons and non-superconducting Cooper pairs can be formed at the interface between the two band insulators LaAlO3 and SrTiO3. Full quantization of conductance is observed for micrometer-length devices, establishing that electron transport takes place with negligible dissipation or scattering. The electron waveguides possess gate and magnetic-field selectable spin and charge degrees of freedom and can be tuned to the one-dimensional limit of a single quantum channel. These complex-oxide-based waveguides provide insights into quantum transport in the extreme 1D limit, in a regime in which electrons have a mutual attraction for one another. The selectable spin and subband quantum numbers of these electron waveguides may be useful for quantum simulation, quantum information processing, spintronics, and sensing.