We develop a robust and versatile platform to define nanostructures at oxide interfaces via patterned top gates. Using LaAlO3/SrTiO3 as a model system, we demonstrate controllable electrostatic confinement of electrons to nanoscale regions in the conducting interface. The excellent gate response, ultra-low leakage currents, and long term stability of these gates allow us to perform a variety of studies in different device geometries from room temperature down to 50 mK. Using a split-gate device we demonstrate the formation of a narrow conducting channel whose width can be controllably reduced via the application of appropriate gate voltages. We also show that a single narrow gate can be used to induce locally a superconducting to insulating transition. Furthermore, in the superconducting regime we see indications of a gate-voltage controlled Josephson effect.
@article{arxiv.1410.2237,
title = {Nanoscale Electrostatic Control of Oxide Interfaces},
author = {Srijit Goswami and Emre Mulazimoglu and Lieven M. K. Vandersypen and Andrea D. Caviglia},
journal= {arXiv preprint arXiv:1410.2237},
year = {2015}
}
Comments
Version after peer review; includes additional data on superconductivity